Transmission device, transmission method, reception device and reception method

ABSTRACT

Convenience is achieved in performing processing depending on decoding capability in a reception side. High-frame-rate ultra-high-definition image data is processed to obtain first image data for acquisition of a base-frame-rate high-definition image, second image data for acquisition of a high-frame-rate high-definition image by being used with the first image data, third image data for acquisition of a base-frame-rate ultra-high-definition image by being used with the first image data, and fourth image data for acquisition of a high-frame-rate ultra-high definition image by being used with the first to third image data. A container is transmitted including a predetermined number of video streams including encoded image data of the first to fourth image data. Information is inserted into the container, the information corresponding to information that is inserted into each of the predetermined number of video streams and associated with image data included in the video streams.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Ser. No. 16/072,542, filed onJul. 25, 2018, which is incorporated by reference. U.S. Ser. No.16/072,542 is a National Stage of PCT/JP2017/004146, filed on Feb. 6,2017, and claims the benefit of priority under 35 U.S.C. § 119 ofJapanese Application No. 2016-023185, filed Feb. 9, 2016.

TECHNICAL FIELD

The present technology relates to a transmission device, a transmissionmethod, a reception device, and a reception method, and morespecifically relates to a transmission device and the like that transmithigh-frame-rate ultra-high-definition image data.

BACKGROUND ART

It is considered that in a reception environment in which a fixedreceiver and a mobile receiver share the same transmission band, theoverall bit rate can be reduced by sharing a stream between an imageservice (video service) intended for a fixed receiver whose definitionis regarded to be high and an image service intended for a mobilereceiver whose definition is regarded to be moderate, compared to aso-called simulcast service that separately performs a service for thefixed receiver and a service for the mobile receiver. For example,Patent Document 1 describes that media encoding is scalably performed togenerate a stream of a base layer for a low definition image service anda stream of an enhancement layer for a high definition image service,and a broadcast signal including the streams is transmitted.

CITATION LIST Patent Document

-   Patent Document 1: Japanese Patent Application National Publication    (Laid-Open) No. 2008-543142

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

An object of the present technology is to achieve convenience inperforming processing depending on decoding capability in a receptionside.

Solutions to Problems

The concept of the present technology is in a transmission deviceincluding:

an image processing unit that processes high-frame-rateultra-high-definition image data to obtain first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata;

a transmission unit that transmits a container including a predeterminednumber of video streams including encoded image data of the first tofourth image data; and

an information insertion unit that inserts information into thecontainer, the information corresponding to information that is insertedinto each of the predetermined number of video streams and associatedwith image data included in the video streams.

In the present technology, high-frame-rate ultra-high-definition imagedata is processed by the image processing unit, and first to fourthimage data are obtained. The first image data is image data foracquisition of a base-frame-rate high-definition image. The second imagedata is image data for acquisition of a high-frame-rate high-definitionimage by being used with the first image data. The third image data isimage data for acquisition of base-frame-rate ultra-high-definitionimage by being used with the first image data. The fourth image data isimage data for acquisition of high-frame-rate ultra-high-definitionimage by being used with the first to third image data.

A container including a predetermined number of video streams includingencoded image data of the first to fourth image data is transmitted bythe transmission unit. Information is inserted into the container by theinformation transmission unit, the information corresponding toinformation that is inserted into each of the predetermined number ofvideo streams and associated with image data included in the videostreams.

For example, it is preferable that the container transmitted by thetransmission unit includes a first video stream including encoded imagedata of the first image data and encoded image data of the second imagedata, and a second video stream including encoded image data of thethird image data and encoded image data of the fourth image data, andthe information insertion unit inserts the information into thecontainer in a state in which the first and second video streams areeach managed with one track. In a case where the container is of MP4(ISOBMFF), information is arranged associated with the encoded imagedata of two image data included in the video stream, in a “moof” blockexisting in correspondence with the track.

In this case, the number of video streams (files) is two and thecontainer becomes simple. A container analysis unit (demultiplexer) of abase-frame-rate receiver, for example, a 60P receiver, needs to read a120P stream and skip an unnecessary picture. On the other hand, ahigh-frame-rate receiver, for example, a 120P receiver, only needs todecode a picture of the 120P stream as it is without doing anythingextra.

In this case, for example, it is preferable that the informationinsertion unit, when inserting the information into the container,performs insertion by grouping information associated with the encodedimage data of the first image data and information associated with theencoded image data of the second image data, for the first video stream,and performs insertion by grouping information associated with theencoded image data of the third image data and information associatedwith the encoded image data of the fourth image data, for the secondvideo stream. Grouping is performed as described above, whereby itbecomes possible to easily determine to which encoded image data eachinformation relates, in the reception side.

In addition, in this case, for example, it is preferable that a pictureof the first image data and a picture of the second image data areencoded alternately, that is, alternately in chronological order, in thefirst video stream, and a picture of the third image data and a pictureof the fourth image data are encoded alternately, that is, alternatelyin chronological order, in the second video stream. Encoding isperformed as described above, whereby it becomes possible to smoothlyperform decoding processing of each picture, in the reception side. Inaddition, encoding is alternately performed as described above, wherebyit guarantees that decoding processing is possible within a range ofdecoding capability in a receiver that decodes only the first image dataor only the first image data and the third image data.

In addition, for example, it is preferable that the containertransmitted by the transmission unit includes a first video streamincluding encoded image data of the first image data and encoded imagedata of the second image data, and a second video stream includingencoded image data of the third image data and encoded image data of thefourth image data, and the information insertion unit inserts theinformation into the container in a state in which the first and secondvideo streams are each managed with two tracks. In a case where thecontainer is of MP4 (ISOBMFF), a “moof” block exists for each track, andinformation is arranged associated with one of the encoded image data ofthe two image data included in the video stream.

In this case, the number of video streams (files) is two and thecontainer becomes simple. A container analysis unit (demultiplexer) of abase-frame-rate receiver, for example, a 60P receiver, needs to read a120P stream and skip an unnecessary picture. On the other hand, ahigh-frame-rate receiver, for example, a 120P receiver, only needs todecode a picture of the 120P stream as it is without doing anythingextra.

In this case, for example, it is preferable that a picture of the firstimage data and a picture of the second image data are encodedalternately, that is, alternately in chronological order, in the firstvideo stream, and a picture of the third image data and a picture of thefourth image data are encoded alternately, that is, alternately inchronological order, in the second video stream. Encoding is performedas described above, whereby it becomes possible to smoothly performdecoding processing of each picture, in the reception side. In addition,encoding is alternately performed as described above, whereby itguarantees that decoding processing is possible within a range ofdecoding capability in a receiver that decodes only the first image dataor only the first image data and the third image data.

In addition, for example, it is preferable that the containertransmitted by the transmission unit includes a first video streamincluding encoded image data of the first image data, a second videostream including encoded image data of the second image data, a thirdvideo stream including encoded image data of the third image data, and afourth video stream including encoded image data of the fourth imagedata, and the information insertion unit inserts the information in astate in which the first to fourth video streams are each managed withone track. In a case where the container is of MP4 (ISOBMFF),information is arranged associated with the encoded image data of oneimage data included in the video stream, in a “moof” block existing incorrespondence with the track.

In this case, the number of video streams (files) is four. Abase-frame-rate receiver, for example, a 60P receiver, guaranteesso-called downward compatibility of reading a 60P stream andtransferring the 60P stream to a decoder without any extra awareness. Onthe other hand, a high-frame-rate receiver, for example, a 120Preceiver, needs to combine two streams and make one stream in thedecoding order to transfer the stream to the decoder.

As described above, in the present technology, information is insertedinto the container, the information corresponding to information that isinserted into each of the predetermined number of video streams andassociated with image data included in the video streams. Therefore, inthe reception side, it becomes easily possible to perform decodingprocessing by extracting predetermined encoded image data from the firstto fourth image data included in the predetermined number of streams, onthe basis of the information, depending on decoding capability.

Note that, in the present technology, for example, it is preferable thatthe high-frame-rate ultra-high-definition image data is transmissionimage data having a high-dynamic-range photoelectric conversioncharacteristic given by performing photoelectric conversion by thehigh-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data, and the information insertion unitfurther inserts conversion characteristic information indicating thehigh-dynamic-range photoelectric conversion characteristic or anelectro-optical conversion characteristic corresponding to thehigh-dynamic-range photoelectric conversion characteristic, into a videostream including encoded image data of the first image data. Forexample, it is preferable that the high-dynamic-range photoelectricconversion characteristic is a characteristic of Hybrid Log-Gamma. Inaddition, for example, it is preferable that the high-dynamic-rangephotoelectric conversion characteristic is a characteristic of a PQcurve. The conversion characteristic information is inserted asdescribed above, whereby it becomes easily possible to performappropriate electro-optical conversion on the basis of the conversioncharacteristic information, in the reception side.

In this case, for example, when the high-dynamic-range photoelectricconversion characteristic is the characteristic of the PQ curve, it ispreferable that the information insertion unit further insertsconversion information for conversion of a value of conversion data bythe characteristic of the PQ curve to a value of conversion data by astandard-dynamic-range photoelectric conversion characteristic, into thevideo stream including the encoded image data of the first image data.The conversion information is inserted as described above, whereby itbecomes possible to satisfactorily obtain display image data in a casewhere standard-dynamic-range display is performed, in the receptionside.

In addition, another concept of the present technology is in

a reception device including

a reception unit that receives a container including a predeterminednumber of video streams, in which

the predetermined number of video streams includes first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata that are obtained by processing high-frame-rateultra-high-definition image data,

information is inserted into the container, the informationcorresponding to information that is inserted into each of thepredetermined number of video streams and associated with image dataincluded in the video streams, and

the reception device further includes a processing unit that obtainsimage data by selectively extracting predetermined encoded image datafrom encoded image data of the first to fourth image data and performingdecoding processing, on the basis of the information inserted into thecontainer, depending on decoding capability.

In the present technology, a container including a predetermined numberof video streams is received by the reception unit. The predeterminednumber of video streams includes encoded image data of the first tofourth image data obtained by processing high-frame-rateultra-high-definition image data. The first image data is image data foracquisition of a base-frame-rate high-definition image. The second imagedata is image data for acquisition of a high-frame-rate high-definitionimage by being used with the first image data. The third image data isimage data for acquisition of base-frame-rate ultra-high-definitionimage by being used with the first image data. The fourth image data isimage data for acquisition of high-frame-rate ultra-high-definitionimage by being used with the first to third image data.

Information is inserted into the container, the informationcorresponding to information that is inserted into each of thepredetermined number of video streams and associated with image dataincluded in the video streams. Predetermined encoded image data isselectively extracted from the encoded image data of the first to fourthimage data, decoding processing is performed, and image data isobtained, on the basis of the information inserted into the container,depending on decoding capability, by the processing unit.

As described above, in the present technology, information is insertedinto the container, the information corresponding to information that isinserted into each of the predetermined number of video streams andassociated with image data included in the video streams, andpredetermined encoded image data is selectively extracted from theencoded image data of the first to fourth image data and decodingprocessing is performed, on the basis of the information inserted intothe container, depending on decoding capability. Therefore, it becomespossible to easily perform decoding processing depending on decodingcapability.

Note that, in the present technology, for example, it is preferable thatthe high-frame-rate ultra-high-definition image data is transmissionimage data having a high-dynamic-range photoelectric conversioncharacteristic given by performing photoelectric conversion by thehigh-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data, conversion characteristic informationindicating the high-dynamic-range photoelectric conversioncharacteristic or an electro-optical conversion characteristiccorresponding to the high-dynamic-range photoelectric conversioncharacteristic is inserted into a video stream including the encodedimage data of the first image data, and the processing unit obtainsdisplay image data by performing electro-optical conversion on the imagedata obtained by the decoding processing on the basis of the conversioncharacteristic information. Electro-optical conversion is performed onthe basis of the conversion characteristic information as describedabove, whereby it becomes easily possible to perform appropriateelectro-optical conversion.

In addition, in the present technology, for example, it is preferablethat the high-frame-rate ultra-high-definition image data istransmission image data having a high-dynamic-range photoelectricconversion characteristic given by performing photoelectric conversionby the high-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data, the high-dynamic-range photoelectricconversion characteristic is a characteristic of a PQ curve, conversioninformation for conversion of a value of conversion data by thecharacteristic of the PQ curve to a value of conversion data by astandard-dynamic-range photoelectric conversion characteristic isinserted into the video stream including the encoded image data of thefirst image data, and the processing unit, when performingstandard-dynamic-range display, obtains standard-dynamic-rangetransmission image data by performing dynamic range conversion on theimage data obtained by the decoding processing on the basis of theconversion information, and obtains display image data by performingelectro-optical conversion by a standard-dynamic-range electro-opticalconversion characteristic on the standard-dynamic-range transmissionimage data. As a result, it becomes possible to satisfactorily obtaindisplay image data in a case where standard-dynamic-range display isperformed.

In addition, another concept of the present technology is in

a transmission device including:

an image processing unit that processes high-frame-rate image data toobtain first image data for acquisition of a base-frame-rate image andsecond image data for acquisition of high-frame-rate image data by beingused with the first image data;

a transmission unit that transmits a container including at least onevideo stream including encoded image data of the first and second imagedata; and

an information insertion unit that inserts a level specification valueof a video stream corresponding to the encoded image data of the firstimage data in correspondence with the encoded image data of the firstimage data, and inserts a level specification value of a video streamobtained by combining the encoded image data of the first and secondimage data in correspondence with the encoded image data of the secondimage data, into the container.

In the present technology, high-frame-rate image data is processed bythe image processing unit, and first image data for acquisition of abase-frame-rate image and second image data for acquisition ofhigh-frame-rate image data by being used with the first image data areobtained. A container including at least one video stream includingencoded image data of the first and second image data is transmitted bythe transmission unit.

Then, a level specification value of a video stream corresponding to theencoded image data of the first image data is inserted in correspondencewith the encoded image data of the first image data, and a levelspecification value of a video stream obtained by combining the encodedimage data of the first and second image data is inserted incorrespondence with the encoded image data of the second image data,into the container, by the information insertion unit.

As described above, in the present technology, the level specificationvalue of the video stream is inserted into the container, whereby itbecomes possible to selectively transfer, to a decoder, encoded imagedata depending on decoding capability from the encoded image data of thefirst and second image data and process the encoded image data, on thebasis of the information of the level specification value of the videostream, in the reception side.

In addition, another concept of the present technology is in

a reception device including:

a reception unit that receives a container including at least one videostream, in which

the at least one video stream includes first image data for acquisitionof a base-frame-rate image and second image data for acquisition ofhigh-frame-rate image data by being used with the first image data,

into the container, a level specification value of a video streamcorresponding to the encoded image data of the first image data isinserted in correspondence with the encoded image data of the firstimage data, and a level specification value of a video stream obtainedby combining the encoded image data of the first and second image datais inserted in correspondence with the encoded image data of the secondimage data, and

the reception device further includes a processing unit that obtainsimage data by selectively extracting at least one encoded image datafrom encoded image data of the first and second image data andperforming decoding processing, on the basis of the level specificationvalue of the video stream inserted into the container, depending ondecoding capability.

In the present technology, a container including at least one videostream is received by the reception unit. Here, the at least one videostream includes first image data for acquisition of a base-frame-rateimage and second image data for acquisition of high-frame-rate imagedata by being used with the first image data.

In addition, a level specification value of a video stream correspondingto the encoded image data of the first image data is inserted incorrespondence with the encoded image data of the first image data, anda level specification value of a video stream obtained by combining theencoded image data of the first and second image data is inserted incorrespondence with the encoded image data of the second image data,into the container.

At least one encoded image data is selectively extracted from theencoded image data of the first and second image data, decodingprocessing is performed, and image data is obtained, on the basis of thelevel specification value of the video stream inserted into thecontainer, depending on decoding capability, by the processing unit.

As described above, in the present technology, on the basis ofinformation of the level specification value of the video streaminserted into the container, encoded image data depending on decodingcapability is selectively transferred to a decoder from the encodedimage data of the first and second image data and is processed, and itbecomes possible to efficiently perform processing in the decoder.

Effects of the Invention

With the present technology, convenience can be achieved in performingprocessing depending on decoding capability in the reception side. Notethat, the advantageous effects described in this specification aremerely examples, and the advantageous effects of the present technologyare not limited to them and may include additional effects.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating an example configuration of anMPEG-DASH based stream distribution system.

FIG. 2 is a diagram illustrating an example of a relationship betweenstructures arranged hierarchically in an MPD file.

FIG. 3 is a block diagram illustrating an example configuration of atransmission/reception system as an embodiment.

FIG. 4 is a diagram illustrating an example of an MP4 stream transmittedthrough a communication network transmission path or an RF transmissionpath.

FIG. 5 is a diagram illustrating an overview of encoding/decodingprocessing in a service transmission system and a service receiver.

FIG. 6 is a diagram for describing first to fourth image data includedin two or four video streams (video files).

FIG. 7 is a diagram illustrating an example configuration of an MP4stream (file) in transmission of Case 1.

FIG. 8 is a diagram illustrating examples of SPS (VPS) elements.

FIG. 9 is a diagram schematically illustrating an example of controlinformation in a “moof (moof 0)” box in the transmission of Case 1.

FIG. 10 is a diagram schematically illustrating an example of controlinformation in a “moof (moof 1)” box in the transmission of Case 1.

FIG. 11 is a diagram illustrating an example configuration of an MP4stream (file) in transmission of Case 2.

FIG. 12 is a diagram schematically illustrating an example of controlinformation in boxes of “moof (moof 0)” and “moof (moof 1)” in thetransmission of Case 2.

FIG. 13 is a diagram schematically illustrating an example of controlinformation in boxes of “moof (moof 2)” and “moof (moof 3)” in thetransmission of Case 2.

FIG. 14 is a diagram illustrating an example configuration of an MP4stream (file) in transmission of Case 3.

FIG. 15 is a diagram illustrating a description example of an MPD filein a case of transmission of a two-stream configuration (in the cases ofCase 1 and Case 2).

FIG. 16 is a diagram illustrating “Value” semantics of“SupplementaryDescriptor”.

FIG. 17 is a diagram illustrating a description example of an MPD filein a case of transmission of a four-stream configuration (in the casesof Case 1 and Case 2).

FIG. 18 is a block diagram illustrating an example configuration of aservice transmission system.

FIG. 19 is a diagram for describing an HDR photoelectric conversioncharacteristic.

FIG. 20 is a diagram for describing conversion information of dynamicrange conversion.

FIG. 21 is a diagram illustrating an access unit at the head of a GOP ina case where an encoding method is HEVC.

FIG. 22 is a diagram illustrating an example structure of a transferfunction SEI message and details of main information in the examplestructure.

FIG. 23 is a diagram illustrating an example structure of a dynamicrange conversion SEI message.

FIG. 24 is a diagram illustrating details of main information in theexample structure of the dynamic range conversion SEI message.

FIG. 25 is a block diagram illustrating an example configuration of aservice receiver.

FIG. 26 is a diagram for describing details of dynamic range conversion.

MODE FOR CARRYING OUT THE INVENTION

The following is a description of a mode for carrying out the invention(hereinafter referred to as the “embodiment”). Note that, descriptionwill be made in the following order.

1. Embodiment

2. Modification

1. Embodiment

[Overview of MPEG-DASH Based Stream Distribution System]

First, an overview of an MPEG-DASH based stream distribution system towhich the present technology can be applied will be described.

FIG. 1(a) illustrates an example configuration of an MPEG-DASH basedstream distribution system 30A. In the example configuration, a mediastream and an MPD file are transmitted through a communication networktransmission path (communication transmission path). The streamdistribution system 30A has a configuration in which N service receivers33-1, 33-2, . . . , 33-N are connected to a DASH stream file server 31and a DASH MPD server 32 via a Content Delivery Network (CDN) 34.

The DASH stream file server 31 generates a stream segment of the DASHspecification (hereinafter referred to as “DASH segment” as appropriate)on the basis of media data (video data, audio data, subtitle data, andthe like) of a predetermined content, and transmits the segment inresponse to an HTTP request from each of the service receivers. The DASHstream file server 31 may be a server dedicated to streaming, or may besubstituted by a web server.

In addition, in response to a request of a segment of a predeterminedstream transmitted from a service receiver 33 (33-1, 33-2, . . . , 33-N)via the CDN 34, the DASH stream file server 31 transmits the segment ofthe stream to a requesting receiver via the CDN 34. In this case, theservice receiver 33 refers to a value of a rate described in a MediaPresentation Description (MPD) file, selects a stream of an optimumrate, and makes a request, depending on a state of a network environmentwhere the client is located.

The DASH MPD server 32 is a server that generates an MPD file foracquiring the DASH segment generated in the DASH stream file server 31.On the basis of content metadata from a content management server (notillustrated) and an address (url) of the segment generated in the DASHstream file server 31, the MPD file is generated. Note that, the DASHstream file server 31 and the DASH MPD server 32 may be physically thesame server.

In an MPD format, each attribute is described by using an element calledRepresentation for each stream such as video and audio. For example, inthe MPD file, the Representation is divided for each of a plurality ofvideo data streams with different rates, and each rate is described. Inthe service receiver 33, with reference to a value of the rate, theoptimum stream can be selected, depending on the state of the networkenvironment where the service receiver 33 is located, as describedabove.

FIG. 1(b) illustrates an example configuration of an MPEG-DASH basedstream distribution system 30B. In the example configuration, a mediastream and an MPD file are transmitted through an RF transmission path(broadcast transmission path). The stream distribution system 30Bincludes a broadcast transmission system 36 to which the DASH streamfile server 31 and the DASH MPD server 32 are connected, and M servicereceivers 35-1, 35-2, . . . , 35-M.

In the case of the stream distribution system 30B, the broadcasttransmission system 36 transmits the stream segment of the DASHspecification (DASH segment) generated in the DASH stream file server 31and the MPD file generated in the DASH MPD server 32 on a broadcastwave.

FIG. 2 illustrates an example of a relationship between structuresarranged hierarchically in the MPD file. As illustrated in FIG. 2(a), ina Media Presentation as an entire MPD file, there is a plurality ofPeriods delimited by time intervals. For example, the first Periodstarts from 0 seconds, the next Period starts from 100 seconds, and soon.

As illustrated in FIG. 2(b), there is a plurality of AdaptationSets inthe Period. AdaptationSets depend on differences in media types such asvideo and audio, and differences in languages, differences inviewpoints, and the like even on the same media type. As illustrated inFIG. 2(c), there is a plurality of Representations in the AdaptationSet.Representations depend on stream attributes, such as differences inrates.

As illustrated in FIG. 2(d), a Representation includes SegmentInfo. Inthe SegmentInfo, as illustrated in FIG. 2(e), there are anInitialization Segment, and a plurality of Media Segments in whichinformation for each Segment obtained by delimiting the Period morefinely is described. In the Media Segment, there is information of anaddress (url) for actual acquisition of segment data such as video andaudio, or the like.

Note that, between the plurality of Representations included in theAdaptationSet, stream switching can be performed freely. As a result,depending on the state of the network environment of the reception side,the stream of the optimum rate can be selected, and uninterrupted videodistribution can be achieved.

[Example Configuration of Transmission/Reception System]

FIG. 3 illustrates an example configuration of a transmission/receptionsystem 10 as an embodiment. The transmission/reception system 10includes a service transmission system 100 and a service receiver 200.In the transmission/reception system 10, the service transmission system100 corresponds to the DASH stream file server 31 and the DASH MPDserver 32 of the stream distribution system 30A illustrated in FIG.1(a). In addition, in the transmission/reception system 10, the servicetransmission system 100 corresponds to the DASH stream file server 31,the DASH MPD server 32, and the broadcast transmission system 36 of thestream distribution system 30B illustrated in FIG. 1(b).

In addition, in the transmission/reception system 10, the servicereceiver 200 corresponds to the service receiver 33 (33-1, 33-2, . . . ,33-N) of the stream distribution system 30A illustrated in FIG. 1(a). Inaddition, in the transmission/reception system 10, the service receiver200 corresponds to a service receiver 35 (35-1, 35-2, . . . , 35-M) ofthe stream distribution system 30B illustrated in FIG. 1(b).

The service transmission system 100 transmits DASH/MP4, that is, MP4 asa container including an MPD file as a metafile and a media stream(Media Segment) such as video or audio, through the communicationnetwork transmission path (see FIG. 1(a)) or the RF transmission path(see FIG. 1(b)).

FIG. 4 illustrates an example of an MP4 stream transmitted through thecommunication network transmission path or the RF transmission path. Theentire service stream is fragmented and transmitted so that images andsounds come out from the middle of transmission in general broadcastingand the like. In this case, as illustrated in the figure, starting froman initialization segment (IS), followed by boxes of “styp”, “Segmentindex box (sidx)”, “Sub-segment index box (ssix)”, “Movie frgment box(moof)”, and “Media data box (mdat)”.

The initialization segment (IS) has a Box structure based on the ISOBase Media File Format (ISOBMFF). At the head, a “ftyp” box indicating afile type is arranged, followed by a “moov” box for control. Althoughdetailed description is omitted, various boxes including a “mvex” boxare included in the “moov” box. Then, a “leva” box is arranged in the“mvex” box. In the “leva” box, an assignment is defined of a Leveldefined by “temporal_layerID”, and grouping of pictures is performed ateach Level, or an individual track is assigned to a Level.

The “styp” box includes segment type information. The “sidx” boxincludes range information of each track, positions of “moof”/“mdat” areindicated, and positions of samples (pictures) in “mdat” are alsoindicated. The “ssix” box includes division information of the tracks,and I/P/B types are classified.

The “moof” box includes control information. The “mdat” box includesentities of signals (transmission media) themselves, such as video andaudio. The “mdat” box and the “mdat” box constitute a Movie Fragment.The “mdat” box of one Movie Fragment includes a fragment obtained byfragmentation of the transmission medium, so that the controlinformation included in the “moof” box is control information associatedwith the fragment. As the size of the fragment, for example, a Group OfPicture (GOP) of MPEG Video or the like is assumed.

In the embodiment, the media stream includes a predetermined number ofvideo streams obtained by processing high-frame-rate (HFR)ultra-high-definition (UHD) image data (moving image data). In theembodiment, the high-frame-rate ultra-high-definition image data is, forexample, 120P 4K/8K image data.

The predetermined number of video streams includes the encoded imagedata of the first to fourth image data. The first image data is baselayer image data for acquisition of a base-frame-rate(normal-frame-rate) high-definition image. The second image data is baselayer image data for acquisition of a high-frame-rate high-definitionimage by being used with the first image data. The third image data isscalable layer image data for acquisition of a base-frame-rateultra-high-definition image by being used with the first image data. Thefourth image data is scalable layer image data for acquisition of ahigh-frame-rate ultra-high-definition image by being used with the firstto third image data.

For example, the first to fourth image data are obtained as follows.That is, the first image data is obtained by applying down-scalingprocessing to fifth image data obtained by extracting each of the firstpictures by down-sampling from two consecutive picture units in thehigh-frame-rate ultra-high-definition image data. Note that, each of thefirst pictures extracted here may be mixed with the second picture at apredetermined ratio. In addition, the second image data is obtained byapplying down-scaling processing to a sixth image data obtained byextracting each of the second pictures by down-sampling from twoconsecutive pictures in the high-frame-rate ultra-high-definition imagedata. Note that, each of the second pictures extracted here may be mixedwith the first picture at a predetermined ratio.

In addition, the third image data is obtained by subtraction between aseventh image data obtained by applying up-scaling processing to thefirst image data and the fifth image data. In addition, the fourth imagedata is obtained by subtraction between an eighth image data obtained byapplying up-scaling processing to the second image data and the sixthimage data.

Information is inserted into the MP4 as the container, the informationcorresponding to information that is inserted into each of thepredetermined number of video streams and associated with image dataincluded in the video streams. For example, the information associatedwith the image data included in the video streams is information such as“general_level_idc”, “general_profile_idc”, “sublayer_level_idc”, and“sublayer_profile_idc” included in sequence Parameter Set (SPS), and theinformation corresponding to these pieces of information is arranged ina “moof” block.

Here, consideration is made on three cases of Case 1, Case 2, and Case 3where the number of video streams (video files) and the number of tracksfor managing each video stream differ from each other.

“Case 1”

The MP4 includes a first video stream including encoded image data ofthe first and second image data that are the base layer image data, anda second video stream including encoded image data of the third andfourth image data that are the scalable layer image data, and the firstand second video streams are each managed with one track.

In this case, a picture of the first image data and a picture of thesecond image data are encoded alternately in the first video stream, anda picture of the third image data and a picture of the fourth image dataare encoded alternately in the second video stream. That is, a picture(sample) included in a base 60P and a picture (sample) included in anenhancement 60P are alternately encoded. Accordingly, values of thedecoding time stamps and display time stamps of the pictures areassigned so that the base 60P and enhancement 60P are alternated.

In addition, in this case, information is arranged in a “moof” blockexisting in correspondence with the track, the information correspondingto information associated with encoded image data of two image dataincluded in the video stream. That is, the information is arranged in astate in which the first and second video streams are each managed withone track. Then, in this case, information associated with the encodedimage data of the first image data and information associated with theencoded image data of the second image data are grouped and inserted forthe first video stream, and the information associated with the encodedimage data of the third image data and the information associated withthe encoded image data of the fourth image data are grouped and insertedfor the second video stream.

“Case 2”

The MP4 includes the first video stream including the encoded image dataof the first and second image data that are the base layer image data,and the second video stream including the encoded image data of thethird and fourth image data that are the scalable layer image data, andthe first and second video streams are each managed with two tracks.

In this case, a picture of the first image data and a picture of thesecond image data are encoded alternately in the first video stream, anda picture of the third image data and a picture of the fourth image dataare encoded alternately in the second video stream. That is, a picture(sample) included in a base 60P and a picture (sample) included in anenhancement 60P are alternately encoded. Accordingly, values of thedecoding time stamps and display time stamps of the pictures areassigned so that the base 60P and enhancement 60P are alternated.

In addition, in this case, a “moof” block exists for each track, andinformation is arranged associated with one of the encoded image data ofthe two image data included in the video stream. That is, theinformation is arranged in a state in which the first and second videostreams are each managed with two tracks.

“Case 3”

The MP4 includes a first video stream including the first encoded imagedata that is the base layer image data, a second video stream includingthe second encoded image data that is the base layer image data, a thirdvideo stream including the encoded image data of the third image datathat is the scalable layer image data, and a fourth video streamincluding the encoded image data of the fourth image data that is thescalable layer image data, and the first to fourth video streams areeach managed with different tracks.

In this case, information is arranged in a “moof” block existing incorrespondence with each track, the information corresponding toinformation associated with encoded image data of one image data of thevideo stream. That is, the information is arranged in a state in whichthe first to fourth video streams are each managed with one track.

The high-frame-rate ultra-high-definition image data as a source of thefirst to fourth image data is, for example, transmission image datahaving a high-dynamic-range photoelectric conversion characteristicgiven by performing photoelectric conversion by the high-dynamic-rangephotoelectric conversion characteristic on high-dynamic-range imagedata. Conversion characteristic information indicating thehigh-dynamic-range photoelectric conversion characteristic or anelectro-optical conversion characteristic corresponding to thehigh-dynamic-range photoelectric conversion characteristic is insertedinto the video stream including the encoded image data of the firstimage data. The high-dynamic-range photoelectric conversioncharacteristics include a characteristic of Hybrid Log-Gamma, acharacteristic of a PQ curve, or the like.

When the high-dynamic-range photoelectric conversion characteristic isthe characteristic of the PQ curve, conversion information forconversion of a value of conversion data by the characteristic of the PQcurve to a value of conversion data by a standard-dynamic-rangephotoelectric conversion characteristic is inserted into the videostream including the encoded image data of the first image data.

The service receiver 200 receives the MP4 as the container describedabove transmitted from the service transmission system 100 through thecommunication network transmission path (see FIG. 1(a)) or the RFtransmission path (see FIG. 1(b)). As described above, the MP4 includesthe predetermined number of video streams including the encoded imagedata of the first to fourth image data. In addition, as described above,information is inserted into the MP4, the information corresponding toinformation that is inserted into each of the predetermined number ofvideo streams and associated with image data included in the videostreams.

The service receiver 200 obtains image data by selectively extractingpredetermined encoded image data from the encoded image data of thefirst to fourth image data and performing decoding processing, on thebasis of the information inserted into the MP4, depending on decodingcapability.

For example, in the case of a receiver having a decoding capabilitycapable of processing base-frame-rate high-definition image data, imagedata is obtained for display of a base-frame-rate high-definition imageby selectively applying decoding processing to the encoded image data ofthe first image data. In addition, for example, in the case of areceiver having a decoding capability capable of processinghigh-frame-rate high-definition image data, image data is obtained fordisplay of a high-frame-rate high-definition image by selectivelyapplying decoding processing to the encoded image data of the first andsecond image data.

In addition, for example, in the case of a receiver having a decodingcapability capable of processing base-frame-rate ultra-high-definitionimage data, image data is obtained for display of a base-frame-rateultra-high-definition image by selectively applying decoding processingto the encoded image data of the first and third image data. Inaddition, for example, in the case of a receiver having a decodingcapability capable of processing high-frame-rate ultra-high-definitionimage data, image data is obtained for display of a high-frame-rateultra-high-definition image by applying decoding processing to theencoded image data of all the first to fourth image data.

In addition, when performing high-dynamic-range display, the servicereceiver 200 obtains high-dynamic-range display image data by performinghigh-dynamic-range electro-optical conversion on the image data obtainedby the decoding processing, on the basis of the conversioncharacteristic information inserted into the MP4 or the video streamincluding the first image data.

In addition, when performing standard-dynamic-range display, in a casewhere the high-dynamic photoelectric conversion characteristic indicatedby the conversion characteristic information is the characteristic ofthe Hybrid Log-Gamma curve, the service receiver 200 obtainsstandard-dynamic-range display image data by performing electro-opticalconversion by a standard-dynamic-range electro-optical conversioncharacteristic directly on the image data obtained by the decodingprocessing.

In addition, when performing standard-dynamic-range display, in a casewhere the high-dynamic photoelectric conversion characteristic indicatedby the conversion characteristic information is the characteristic ofthe PQ curve, the service receiver 200 obtains standard-dynamic-rangetransmission image data by performing dynamic range conversion on theimage data obtained by the decoding processing on the basis of theconversion information inserted into the video stream including thefirst image data, and obtains standard-dynamic-range display image databy performing electro-optical conversion by the standard-dynamic-rangeelectro-optical conversion characteristic on the standard-dynamic-rangetransmission image data.

FIG. 5 illustrates an overview of encoding/decoding processing in theservice transmission system 100 and the service receiver 200.High-frame-rate (HFR) ultra-high-definition (UHD) image data “HFR/UHDvideo” is input to a video encoder 104 of the service transmissionsystem 100. In the video encoder 104, the image data “HFR/UHD video” isprocessed, and two video streams including the encoded image data of thefirst to fourth image data (in the cases of Case 1 and Case 2), or fourvideo streams (in the case of Case 3) are obtained and transmitted.

In a service receiver 200A having a decoding capability capable ofprocessing high-frame-rate ultra-high-definition image data, in a videodecoder 204A, decoding processing is applied to the encoded image dataof all the first to fourth image data, and image data “HFR/UHD video” isobtained for display of a high-frame-rate ultra-high-definition image.

In addition, in a service receiver 200B having a decoding capabilitycapable of processing base-frame-rate ultra-high-definition image data,in a video decoder 204B, decoding processing is selectively applied tothe encoded image data of the first and third image data, and image data“LFR/UHD video” is obtained for display of a base-frame-rateultra-high-definition image.

In addition, in a service receiver 200C having a decoding capabilitycapable of processing high-frame-rate high-definition image data, in avideo decoder 204C, decoding processing is selectively applied to theencoded image data of the first and second image data, and image data“HFR/HD video” is obtained for display of a high-frame-ratehigh-definition image.

In addition, in a service receiver 200D having a decoding capabilitycapable of processing base-frame-rate high-definition image data, in avideo decoder 204D, decoding processing is selectively applied to theencoded image data of the first image data, and image data “LFR/HDvideo” is obtained for display of a base-frame-rate high-definitionimage.

FIG. 6 illustrates hierarchically the above-described first to fourthimage data. In the illustrated example, a case is illustrated where thehigh frame rate is 120P. The horizontal axis indicates display order(picture order of composition: POC), and display time comes early in theleft side and display time comes late in the right side. Each ofrectangular frames indicates a picture.

First image data “HD 60P” that is the base layer image data exists inthe lowermost row, and its group ID (group_id) is set to “0”. The firstimage data is image data constituting the base 60P, and its temporallayer ID (TemporalLayerId) is set to “0”.

In addition, second image data “HD+60P HFR” that is the base layer imagedata exists in the upper row of the first image data, and its group ID(group_id) is set to “1”. The second image data is image dataconstituting the enhancement 60P for 120P image data, and its temporallayer ID (TemporalLayerId) is set to “1”. The second image data istemporal scalability with respect to the first image data “HD 60P”.

As described above, in Case 1 and Case 2, the first and second imagedata are transmitted as the same video stream (video file). Byperforming grouping by the group ID, in a case where only the base 60Pis decoded, the group ID can be used as a criterion for determiningwhich packet should be transmitted to the video decoder. In a case whereboth the base 60P and the enhancement 60 are decoded, packets of thebase 60P and the enhancement 60P only need to be alternately transmittedto the video decoder.

In addition, third image data “Sc-UHD 60P” that is the scalable layerimage data exists in the upper row of the second image data, and itsgroup ID (group_id) is set to “2”. The third image data is image dataconstituting the base 60P, and its temporal layer ID (TemporalLayerId)is set to “0”. The third image data is spatial scalability with respectto the first image data “HD 60P”.

In addition, fourth image data “Sc-UHD+60P HFR” that is the scalablelayer image data exists in the upper row of the third image data, andits group ID (group_id) is set to “3”. The fourth image data is imagedata constituting the enhancement 60P for 120P image data, and itstemporal layer ID (TemporalLayerId) is set to “1”. The fourth image datais temporal scalability with respect to the third image data “Sc-UHD60P” and spatial scalability with respect to the second “HD+60P HFR”.

As described above, in Case 1 and Case 2, the third and fourth imagedata are transmitted as the same video stream (video file). Byperforming grouping by the group ID, in a case where only the base 60Pis decoded, the group ID can be used as a criterion for determiningwhich packet should be transmitted to the decoder. In a case where boththe base 60P and the enhancement 60 are decoded, packets of the base 60Pand the enhancement 60P only need to be alternately transmitted to thevideo decoder.

On the basis of the first image data “HD 60P”, it is possible toreproduce a base-frame-rate high-definition (HD) image (60P HD image).In addition, on the basis of the first image data “HD 60P” and thesecond “HD+60P HFR”, it is possible to reproduce a high-frame-ratehigh-definition (HD) image (120P HD image).

In addition, on the basis of the first image data “HD 60P” and the thirdimage data “Sc-UHD 60P”, it is possible to reproduce a base-frame-rateultra-high-definition (UHD) image (60P UHD image). In addition, on thebasis of the first image data “HD 60P”, the second image data “HD+60PHFR”, the third image data “Sc-UHD 60P”, and the fourth image data“Sc-UHD+60P HFR”, it is possible to reproduce high-frame-rateultra-high-definition (UHD) images (120P UHD images).

Note that, the numbers given to the rectangular frames indicating thepictures indicate the encoding order, and hence the decoding order. In acase where decoding processing is performed only on the encoded imagedata of the first image data, decoding is performed in the order of0→4→8→ . . . . In addition, in a case where decoding processing isperformed on the first and second image data, decoding is performed inthe order of 0→2→4→6→ . . . . Furthermore, in a case where decodingprocessing is performed on the first and third image data, decoding isperformed in the order of 0→1→4→5→ . . . . Further, in a case wheredecoding processing is performed on the first to fourth image data,decoding is performed in the order of 0→1→2→3→4→5→ . . . . Regardless ofan arrangement method of the first to fourth image data in the stream,in the case of broadcast distribution, the encoding order of the imagesis set in the order of 0→1→2→3→4→5→ . . . . With this setting, it ispossible to minimize the delay from reception to display.

Regarding the encoding order in the stream, in a case where the firstimage data and the second image data are included in the same videostream, the picture of the first image data and the picture of thesecond image data are encoded alternately. Similarly, in a case wherethe third image data and the fourth image data are included in the samevideo stream, the picture of the third image data and the picture of thefourth image data are encoded alternately.

FIG. 7 illustrates an example configuration of an MP4 stream (file) inCase 1. In the illustrated example, illustration is omitted of theinitialization segment (IS) and the boxes of “styp”, “sidx”, and “ssix”enclosed by broken line frames in FIG. 4. The illustrated example is anexample of Fragmented MP4. In the MP4 stream, a predetermined number ofMovie Fragments is arranged each including a “moof” box includingcontrol information and a “mdat” box including the body of the mediadata. The “mdat” box includes fragments obtained by fragmentation oftrack data, so that the control information included in the “moof” boxis control information associated with the fragments.

In the MP4 stream including the first video stream including the encodedimage data of the first and second image data of the Base Layer, in the“mdat” box, the encoded image data (access unit) of the first and secondimage data are arranged for a predetermined number of pictures, forexample, for one GOP. In this case, the Access Unit (AU) of the firstimage data and the Access Unit of the second image data are arrangedalternately. Note that, the position of each access unit is indicated byinformation in the “SIDX” box or “SSIX” box. Each access unit includesNAL units such as “VPS”, “SPS”, “PPS”, “SEI”, and “SLC”. Note that,“VPS” and “SPS” are inserted into, for example, the access unit at thehead of the GOP.

FIG. 8 illustrates examples of SPS (VPS) elements. The example is anexample in a case where the first to fourth image data are configured asillustrated in FIG. 6. The value of “general_level_idc” is set to “156”,and it is indicated that the overall level of the encoded image data ofthe first to fourth image data (the complexity difference of the pixelrate of the scalable encoding) is “level 5.2”. In addition, the value of“general_profile_idc” is set to “7”, and it is indicated that theoverall profile (scalable encoding type) of the encoded image data ofthe first to fourth image data is “Scalable Main 10 Profile”.

In addition, “sublayer_level_present_flag[j−1]” is set to “1”, the valueof “sublayer_level_idc[j−1]” is set to “153”, and“sublayer_profile_idc[j−1]” is set to “7”. As a result, it is indicatedthat the overall level of the encoded image data of the third and firstimage data is “level 5.1”, and its profile is “Scalable Main 10Profile”.

In addition, “sublayer_level_present_flag[j−2]” is set to “1”, the valueof “sublayer_level_idc[j−2]” is set to “150”, and“sublayer_profile_idc[j−2]” is set to “2”. As a result, it is indicatedthat the overall level of the encoded image data of the second and firstimage data is “level 5”, and its profile is “Main 10 Profile”.

In addition, “sublayer_level_present_flag[j−3]” is set to “1”, the valueof “sublayer_level_idc[j−3]” is set to “123”, and“sublayer_profile_idc[j−3]” is set to “2”. As a result, it is indicatedthat the level of the encoded image data of the first image data is“level 4.1”, and its profile is “Main 10 Profile”.

Referring back to FIG. 7, in the MP4 stream including the first videostream including the encoded image data of the first and second imagedata of the Base Layer, the first video stream is managed with onetrack, and there is one “moof” box (moof 0) corresponding to the “mdat”block. In the “moof (moof 0)” box, there are control information formanagement of the encoded image data of the first image data in the“mdat” block, and control information for management of the encodedimage data of the second image data in the “mdat” block. These twopieces of control information are grouped by the group ID (group_id) inthe “mdat” block and managed.

Although details in the “moof (moof 0)” box will be described later, inthe “moof (moof 0)” box, there is a “tscl” box corresponding to theencoded image data of the first image data in the “mdat” block. In the“tscl” box, there is a description of “temporalLayerId=0”, for example,and it is indicated that the first image data corresponds to a picture(sample) included in the base 60P. In addition, in the “tscl” box, thereis a description of “tllevel_idc=123”, and it is indicated that thelevel of the encoded image data of the first image data is “level 4.1”.In addition, in the “tscl” box, there is a description of“Tlprofile_idc=2”, and it is indicated that the profile of the encodedimage data of the first image data is “Main 10 Profile”.

In addition, in the “moof (moof 0)” box, there is a “tscl” boxcorresponding to the encoded image data of the second image data in the“mdat” block. In the “tscl” box, there is a description of“temporalLayerId=1”, for example, and it is indicated that the secondimage data corresponds to a picture (sample) included in the enhancement60P. In addition, in the “tscl” box, there is a description of“tllevel_idc=150”, and it is indicated that the overall level of theencoded image data of the second and first image data is “level 5”. Inaddition, in the “tscl” box, there is a description of“Tlprofile_idc=2”, and it is indicated that the overall profile of theencoded image data of the second and first image data is “Main 10Profile”.

On the other hand, in the MP4 stream including the second video streamincluding the encoded image data of the third and fourth image data ofthe Scalable Layer, in the “mdat” box, the encoded image data (accessunit) of the third and fourth image data are arranged for apredetermined number of pictures, for example, for one GOP. In thiscase, the Access Unit (AU) of the third image data and the Access Unitof the fourth image data are arranged alternately. Note that, theposition of each access unit is indicated by information in the “SIDX”box or “SSIX” box. Each access unit includes NAL units such as “PPS”,“SEI”, and “SLC”.

Note that, for reference from the Scalable Layer to the Base Layer, anextractor NAL unit is arranged just before all the access units. In theillustrated example, a numerical value illustrated in a rectangularframe indicating each access unit indicates the decoding order. Thisalso applies to a similar figure below. For example, in a case where theaccess unit of “1” is decoded, it is necessary to refer to the accessunit of “0”, and in this case, a decoding result of the access unit of“0” is copied to the extractor arranged just before the access unit of“1” and used.

Within the layer, a decoding time stamp is given so that the decodingorder of 120P in the Base Layer becomes 0→2→4→6→ . . . . With thisdecoding time stamp, the decoding order of 60P becomes 0→4→ . . . . Thatis, the base 60P and enhancement 60P are set so that the time stampvalues are alternated in both the display order and the decoding order.

In addition, in the MP4 stream including the second video streamincluding the encoded image data of the third and fourth image data ofthe Scalable Layer, the second video stream is managed with one track,and there is one “moof” box (moof 1) corresponding to the “mdat” block.In the “moof (moof 1)” box, there are control information for managementof the encoded image data of the third image data in the “mdat” block,and control information for management of the encoded image data of thefourth image data in the “mdat” block. These two pieces of controlinformation are grouped by the group ID (group_id) in the “mdat” blockand managed.

Although details in the “moof (moof 1)” box will be described later, inthe “moof (moof 1)” box, there is a “tscl” box corresponding to theencoded image data of the third image data in the “mdat” block. In the“tscl” box, there is a description of “temporalLayerId=0”, for example,and it is indicated that the third image data corresponds to a picture(sample) included in the base 60P. In addition, in the “tscl” box, thereis a description of “tllevel_idc=153”, and it is indicated that theoverall level of the encoded image data of the third and first imagedata is “level 5.1”. In addition, in the “tscl” box, there is adescription of “Tlprofile_idc=7”, and it is indicated that the overallprofile of the encoded image data of the third and first image data is“Scalable Main 10 Profile”.

In addition, in the “moof (moof 1)” box, there is a “tscl” boxcorresponding to the encoded image data of the fourth image data in the“mdat” block. In the “tscl” box, there is a description of“temporalLayerId=1”, for example, and it is indicated that the fourthimage data corresponds to a picture (sample) included in the enhancement60P. In addition, in the “tscl” box, there is a description of“tllevel_idc=156”, and it is indicated that the overall level of theencoded image data of the first to fourth image data is “level 5.2”. Inaddition, in the “tscl” box, there is a description of“Tlprofile_idc=7”, and it is indicated that the overall profile of theencoded image data of the first to fourth image data is “Scalable Main10 Profile”.

Note that, in the example of FIG. 7, the transmission order of eachsample (picture) is set in the order of 0→1→2→3→4→5→ . . . . With thissetting, it is possible to minimize the delay from reception to display.

FIG. 9 schematically illustrates an example of control information inthe “moof (moof 0)” box. Note that, in the MP4 stream, how the layerwith scalability is mapped is indicated by the “leva (levelassignement)” box of the initialization segment (IS) existing incorrespondence with the “moof (moof 0)” box. Here, the loop is repeatedby the number of times of the level, and “Track_id”, “assignment_type”,and “grouping_type” are specified for each loop. In the “leva” box,there is a description of “level_count=2”, and it is indicated thatthere are two levels “level0, level1” in one track “TR0”.

The method of defining the group ID is as follows. To define a groupwithin a track, there are first and second methods below. In the firstmethod, “grouping_type” is defined as “temporal_layer_group” for eachlevel, and group identification is performed inside the “moof” block.This mode can be set with “assignment_type=0”. In the second method,“sub_track_id” is defined within a track for each level, and its valueis made to coincide with “group_id” in the “moof” block. This mode canbe set with “assignment_type=4”.

In addition, to define a group between tracks, there is a third methodbelow. It is a method of identifying a relationship between tracks byperforming group identification by another track identification(track_id), and defining “grouping_type” as “temporal_layer_group”. Thismode can be set with “assignment_type=2”.

In the illustrated example, in the “leva” box, there is a description of“level_count=2”, and it is indicated that there are two levels “level0,level1” in one track “TR0”. In the first method, in the “leva” box,“assignment_type=0” is described to indicate that it is the firstmethod, and further, “grouping_type=1” is described corresponding toeach of the two levels to indicate that the grouping type of each levelis a temporal layer group.

On the other hand, in the second method, in the “leva” box,“assignment_type=4” is described to indicate that it is the secondmethod, and further, “sub_track_id=0” and “sub_track_id=1” are describedcorresponding to each of the two levels, and “sub_track_id” is definedfor each level. Note that, the value of “sub_track_id” can also beassigned to “group_id”.

There is a “traf” box in the “moof (moof 0)” box, and there is a “tfhd”box in the box. There is a description of a track ID “track_id” in the“tfhd” box, and it is indicated that the track is “TR0”. In addition,there is the “traf” box in the “moof (moof 0)” box, and there is a“tfdt” box in the box. In the “tfdt” box, there is a description ofdecoding time “baseMediaDecodeTime” of the first access unit after the“moof (moof 0)” box.

In addition, there is the “traf” box in the “moof (moof 0)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the decoding order and display order of thebase 60P and enhancement 60P.

In addition, there is the “tfdt” box in the “moof (moof 0)” box, andthere are two “sgpd” boxes in the box. In the first “sgpd” box,information is arranged associated with the first image data. In the“sgpd” box, there is a description of the parameter of “grouping_type”.Here, “grouping_type=1” is set, and it is indicated that the groupingtype is a temporal layer group.

In addition, there is a “scif” box under the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=0” is set, and it is indicated that the group ID is “0”. Inaddition, “primary_groupID” is described together with “group_id”. Thisalso applies to each description part of “group_id” below. This is foridentifying that the group in which the value of “group_id” coincideswith the value of “primary_groupID” is a base 60P group. Here, since“group_id=0” is equal to the value of “primary_groupID”, this group isidentified as the base 60P group.

In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “0”, it is indicated that the firstimage data corresponds to a picture (sample) included in the base 60P.By setting “tlConstantFrameRate” to “1”, it is indicated that the framerate is constant. “tllevel_idc” indicates the level of the encoded imagedata of the first image data, and is made to coincide with“sublayer_level_idc[j−3]” of the element of the SPS (or VPS) describedabove. Here, “tllevel_idc” is set to “123”. “Tlprofile” indicates theprofile of the encoded image data of the first image data, and is madeto coincide with “sublayer_profile_idc[j−3]” of the element of the SPS(or VPS) described above. Here, “Tlprofile” is set to “2”.

In the second “sgpd” box, information is arranged associated with thesecond image data. In the “sgpd” box, there is a description of theparameter of “grouping_type”. Here, “grouping_type=1” is set, and it isindicated that the grouping type is a temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. In thiscase, “group_id=1” is set, and it is indicated that the group ID is “1”.In addition, “primary_groupID” is described together with “group_id”.Here, since “group_id=1” does not coincide with the value of“primary_groupID”, this group is not identified as the base 60P group.In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “1”, it is indicated that the secondimage data corresponds to a picture (sample) included in the enhancement60P. By setting “tlConstantFrameRate” to “1”, it is indicated that theframe rate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the second and first image data, and is made tocoincide with “sublayer_level_idc[j−2]” of the element of the SPS (orVPS) described above. Here, “tllevel_idc” is set to “150”. “Tlprofile”indicates the profile of the encoded image data of the second and firstimage data, and is made to coincide with “sublayer_profile_idc[j−2]” ofthe element of the SPS (or VPS) described above. Here, “Tlprofile” isset to “2”.

FIG. 10 schematically illustrates an example of control information inthe “moof (moof 1)” box. In the “leva” box, there is a description of“level_count=2”, and it is indicated that there are two levels “level0,level1” in one track “TR0”. In the first method, in the “leva” box,“assignment_type=0” is described to indicate that it is the firstmethod, and further, “grouping_type=1” is described corresponding toeach of the two levels to indicate that the grouping type of each levelis a temporal layer group.

On the other hand, in the second method, in the “leva” box,“assignment_type=4” is described to indicate that it is the secondmethod, and further, “sub_track_id=2” and “sub_track_id=3” are describedcorresponding to each of the two levels, and “sub_track_id” is definedfor each level. Note that, the value of “sub_track_id” can also beassigned to “group_id”.

There is a “traf” box in the “moof (moof 1)” box, and there is a “tfhd”box in the box. There is a description of a track ID “track_id” in the“tfhd” box, and it is indicated that the track is “TR1”. In addition,there is the “traf” box in the “moof (moof 1)” box, and there is a“tfdt” box in the box. In the “tfdt” box, there is a description ofdecoding time “baseMediaDecodeTime” of the first access unit after the“moof (moof 1)” box. The decoding time “baseMediaDecodeTime” is set tothe same value as of the decoding time “baseMediaDecodeTime” of thetrack TR0 pointed by the extractor.

In addition, there is the “traf” box in the “moof (moof 1)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the display order and decoding order of thebase 60P and enhancement 60P.

In addition, there is the “tfdt” box in the “moof (moof 1)” box, andthere are two consecutive “sgpd” boxes in the box. In the first “sgpd”box, information is arranged associated with the first image data. Inthe “sgpd” box, there is a description of the parameter of“grouping_type”. Here, “grouping_type=1” is set, and it is indicatedthat the grouping type is a temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=2” is set, and it is indicated that the group ID is “2”. Inaddition, “primary_groupID” is described together with “group_id”. Here,since “group_id=2 does not coincide with the value of “primary_groupID”,this group is not identified as the base 60P group. In addition, thereis a “tscl” box in the “sgpd” box. In the “tscl” box, there aredescriptions of four parameters of “temporalLayerId”, “tllevel_idc”,“Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “0”, it is indicated that the thirdimage data corresponds to a picture (sample) included in the base 60P.By setting “tlConstantFrameRate” to “1”, it is indicated that the framerate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the third and first image data, and is made tocoincide with “sublayer_level_idc[j−1]” of the element of the SPS (orVPS) described above. Here, “tllevel_idc” is set to “153”. “Tlprofile”indicates the overall profile of the encoded image data of the third andfirst image data, and is made to coincide with“sublayer_profile_idc[j−1]” of the element of the SPS (or VPS) describedabove. Here, “Tlprofile” is set to “7”.

In the next “sgpd” box, information is arranged associated with thefourth image data. In the “sgpd” box, there is a description of theparameter of “grouping_type”. Here, “grouping_type=1” is set, and it isindicated that the grouping type is a temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=3” is set, and it is indicated that the group ID is “3”. Inaddition, “primary_groupID” is described together with “group_id”. Here,since “group_id=3” does not coincide with the value of“primary_groupID”, this group is not identified as the base 60P group.In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “1”, it is indicated that the fourthimage data corresponds to a picture (sample) included in the enhancement60P. By setting “tlConstantFrameRate” to “1”, it is indicated that theframe rate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the fourth to first image data, and is made tocoincide with the “general_level_idc” of the element of the SPS (or VPS)described above. Here, “tllevel_idc” is set to “156”. “Tlprofile”indicates the profile of the entire encoded image data of the encodedimage data of the fourth to first image data, and is made to coincidewith the “general_profile_idc” of the element of the SPS (or VPS)described above. Here, “Tlprofile” is set to “7”.

FIG. 11 illustrates an example configuration of an MP4 stream (file) inCase 2. In the illustrated example, illustration is omitted of theinitialization segment (IS) and the boxes of “styp”, “sidx”, and “ssix”enclosed by broken line frames in FIG. 4. The illustrated example is anexample of Fragmented MP4. In the MP4 stream, a predetermined number ofMovie Fragments is arranged each including a “moof” box includingcontrol information and a “mdat” box including the body of the mediadata. The “mdat” box includes fragments obtained by fragmentation oftrack data, so that the control information included in the “moof” boxis control information associated with the fragments.

In the MP4 stream including the first video stream including the encodedimage data of the first and second image data of the Base Layer, in the“mdat” box, the encoded image data (access unit) of the first and secondimage data are arranged for a predetermined number of pictures, forexample, for one GOP. In this case, the Access Unit (AU) of the firstimage data and the Access Unit of the second image data are arrangedalternately. Note that, the position of each access unit is indicated byinformation in the “SIDX” box or “SSIX” box. Each access unit includesNAL units such as “VPS”, “SPS”, “PPS”, “SEI”, and “SLC”. Note that,“VPS” and “SPS” are inserted into, for example, the access unit at thehead of the GOP.

Note that, for reference from the access unit of the second image datato the access unit of the first image data of another track, anextractor NAL unit is arranged just before the access unit of the secondimage data. For example, in a case where the access unit of “2” isdecoded, it is necessary to refer to the access unit of “0”, and in thiscase, a decoding result of the access unit of “0” is copied to theextractor arranged just before the access unit of “2” and used.

In the MP4 stream including the first video stream including the encodedimage data of the first and second image data of the Base Layer, thefirst video stream is managed with two tracks, and there are two “moof”boxes (moof 0, moof 1) corresponding to the “mdat” block. In the “moof(moof 0)” box, there is control information for management of theencoded image data of the first image data in the “mdat” block.

Although details in the “moof (moof 0)” box will be described later,there is a “tscl” box in the “moof (moof 0)” box. In the “tscl” box,there is a description of “temporalLayerId=0”, for example, and it isindicated that the first image data corresponds to a picture (sample)included in the base 60P. In addition, in the “tscl” box, there is adescription of “tllevel_idc=123”, and it is indicated that the level ofthe encoded image data of the first image data is “level 4.1”. Inaddition, in the “tscl” box, there is a description of“Tlprofile_idc=2”, and it is indicated that the profile of the encodedimage data of the first image data is “Main 10 Profile”.

In addition, although details in the “moof (moof 1)” box will bedescribed later, there is a “tscl” box in the “moof (moof 1)” box. Inthe “tscl” box, there is a description of “temporalLayerId=1”, forexample, and it is indicated that the second image data corresponds to apicture (sample) included in the enhancement 60P. In addition, in the“tscl” box, there is a description of “tllevel_idc=150”, and it isindicated that the overall level of the encoded image data of the secondand first image data is “level 5”. In addition, in the “tscl” box, thereis a description of “Tlprofile_idc=2”, and it is indicated that theoverall profile of the encoded image data of the second and first imagedata is “Main 10 Profile”.

On the other hand, in the MP4 stream including the second video streamincluding the encoded image data of the third and fourth image data ofthe Scalable Layer, in the “mdat” box, the encoded image data (accessunit) of the third and fourth image data are arranged for apredetermined number of pictures, for example, for one GOP. In thiscase, the Access Unit (AU) of the third image data and the Access Unitof the fourth image data are arranged alternately. Note that, theposition of each access unit is indicated by information in the “SIDX”box or “SSIX” box. Each access unit includes NAL units such as “PPS”,“SEI”, and “SLC”.

Note that, for reference from the Scalable Layer to the Base Layer andadditionally for reference from the access unit of the fourth image datato the access unit of the third image data of another track, anextractor NAL unit is arranged just before all the access units. Forexample, in a case where the access unit of “1” is decoded, it isnecessary to refer to the access unit of “0”, and in this case, adecoding result of the access unit of “0” is copied to the extractorarranged just before the access unit of “1” and used.

Within the layer, a decoding time stamp is given so that the decodingorder of 120P in the Base Layer becomes 0→2→4→6→ . . . . With thisdecoding time stamp, the decoding order of 60P becomes 0→4→ . . . . Thatis, the base 60P and enhancement 60P are set so that the time stampvalues are alternated in both the display order and the decoding order.

In addition, in the MP4 stream including the second video streamincluding the encoded image data of the third and fourth image data ofthe Scalable Layer, the second video stream is managed with two tracks,and there are two “moof” boxes (moof 2, moof 3) corresponding to the“mdat” block. In the “moof (moof 2)” box, there is control informationfor management of the encoded image data of the third image data in the“mdat” block.

Although details in the “moof (moof 2)” box will be described later,there is a “tscl” box in the “moof (moof 2)” box. In the “tscl” box,there is a description of “temporalLayerId=0”, for example, and it isindicated that the third image data corresponds to a picture (sample)included in the base 60P. In addition, in the “tscl” box, there is adescription of “tllevel_idc=153”, and it is indicated that the overalllevel of the encoded image data of the third and first image data is“level 5.1”. In addition, in the “tscl” box, there is a description of“Tlprofile_idc=7”, and it is indicated that the overall profile of theencoded image data of the third and first image data is “Scalable Main10 Profile”.

In addition, although details in the “moof (moof 3)” box will bedescribed later, there is a “tscl” box in the “moof (moof 3)” box. Inthe “tscl” box, there is a description of “temporalLayerId=1”, forexample, and it is indicated that the fourth image data corresponds to apicture (sample) included in the enhancement 60P. In addition, in the“tscl” box, there is a description of “tllevel_idc=156”, and it isindicated that the overall level of the encoded image data of the fourthto first image data is “level 5.2”. In addition, in the “tscl” box,there is a description of “Tlprofile_idc=7”, and it is indicated thatthe overall profile of the encoded image data of the fourth to firstimage data is “Scalable Main 10 Profile”.

Note that, in the example of FIG. 11, the transmission order of eachsample (picture) is set in the order of 0→1→2→3→4→5→ . . . . With thissetting, it is possible to minimize the delay from reception to display.

FIG. 12 schematically illustrates an example of control information inthe “moof (moof 0)” box and the “moof (moof 1)” box. Note that, in theMP4 stream, how the layer with scalability is mapped is indicated by the“leva (level assignement)” box of the initialization segment (IS)existing in correspondence with these “moof” boxes. Here, the loop isrepeated by the number of times of the level, and “Track_id”,“grouping_type”, and “assignment_type” are specified for each loop.

In the illustrated example, in the “leva” box, there is a description of“level_count=2”, and it is indicated that there is one level in each ofthe two tracks “TR0” and “TR1”. In addition, in the “leva” box,“assignment_type=2” is described corresponding to the level of the twotracks to indicate that it is the third method, and further,“grouping_type=1” is described corresponding to the level of the twotracks, and it is indicated that the grouping type of each level is atemporal layer group.

There is a “traf” box in the “moof (moof 0)” box, and there is a “tfhd”box in the box. There is a description of a track ID “track_id” in the“tfhd” box, and it is indicated that the track is “TR0”. In addition,there is the “traf” box in the “moof (moof 0)” box, and there is a“tfdt” box in the box. In the “tfdt” box, there is a description ofdecoding time “baseMediaDecodeTime” of the first access unit after the“moof (moof 0)” box.

In addition, there is the “traf” box in the “moof (moof 1)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the display order and decoding order of thebase 60P.

In addition, there is the “tfdt” box in the “moof (moof 0)” box, andthere is a “sgpd” box in the box. In the “sgpd” box, information isarranged associated with the first image data. In the “sgpd” box, thereis a description of the parameter of “grouping_type”. Here,“grouping_type=1” is set, and it is indicated that the grouping type isa temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=0” is set, and it is indicated that the group ID is “0”. Inaddition, “primary_groupID” is described together with “group_id”. Here,since “group_id=0” is equal to the value of “primary_groupID”, thisgroup is identified as the base 60P group. In addition, there is a“tscl” box in the “sgpd” box. In the “tscl” box, there are descriptionsof four parameters of “temporalLayerId”, “tllevel_idc”, “Tlprofile”, and“tlConstantFrameRate”.

By setting “temporalLayerId” to “0”, it is indicated that the firstimage data corresponds to a picture (sample) included in the base 60P.By setting “tlConstantFrameRate” to “1”, it is indicated that the framerate is constant. “tllevel_idc” indicates the level of the encoded imagedata of the first image data, and is made to coincide with“sublayer_level_idc[j−3]” of the element of the SPS (or VPS) describedabove. Here, “tllevel_idc” is set to “123”. “Tlprofile” indicates theprofile of the encoded image data of the first image data, and is madeto coincide with “sublayer_profile_idc[j−3]” of the element of the SPS(or VPS) described above. Here, “Tlprofile” is set to “2”.

On the other hand, there is a “traf” box in the “moof (moof 1)” box, andthere is a “tfhd” box in the box. There is a description of a track ID“track_id” in the “tfhd” box, and it is indicated that the track is“TR1”. In addition, there is the “traf” box in the “moof (moof 1)” box,and there is a “tfdt” box in the box. In the “tfdt” box, there is adescription of decoding time “baseMediaDecodeTime” of the first accessunit after the “moof (moof 1)” box. The decoding time“baseMediaDecodeTime” is set to the same value as of the decoding time“baseMediaDecodeTime” of the track TR0 pointed by the extractor.

In addition, there is the “traf” box in the “moof (moof 1)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the display order and decoding order of theenhancement 60P.

In addition, there is the “tfdt” box in the “moof (moof 1)” box, andthere is a “sgpd” box in the box. In the “sgpd” box, information isarranged associated with the second image data. In the “sgpd” box, thereis a description of the parameter of “grouping_type”. Here,“grouping_type=1” is set, and it is indicated that the grouping_type isa temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. In thiscase, “group_id=1” is set, and it is indicated that the group ID is “1”.In addition, “primary_groupID” is described together with “group_id”.Here, since “group_id=1” does not coincide with the value of“primary_groupID”, this group is not identified as the base 60P group.In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “1”, it is indicated that the secondimage data corresponds to a picture (sample) included in the enhancement60P. By setting “tlConstantFrameRate” to “1”, it is indicated that theframe rate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the second and first image data, and is made tocoincide with “sublayer_level_idc[j−2]” of the element of the SPS (orVPS) described above. Here, “tllevel_idc” is set to “150”. “Tlprofile”indicates the overall profile of the encoded image data of the secondand first image data, and is made to coincide with“sublayer_profile_idc[j−2]” of the element of the SPS (or VPS) describedabove. Here, “Tlprofile” is set to “2”.

FIG. 13 schematically illustrates an example of control information inthe “moof (moof 2)” box and the “moof (moof 3)” box. In the illustratedexample, in the “leva” box, there is a description of “level_count=2”,and it is indicated that there is one level in each of the two tracks“TR2” and “TR3”. In addition, in the “leva” box, “assignment_type=2” isdescribed corresponding to the level of the two tracks to indicate thatit is the third method, and further, “grouping_type=1” is describedcorresponding to the level of the two tracks, and it is indicated thatthe grouping type of each level is a temporal layer group.

There is a “traf” box in the “moof (moof 2)” box, and there is a “tfhd”box in the box. There is a description of a track ID “track_id” in the“tfhd” box, and it is indicated that the track is “TR2”. In addition,there is the “traf” box in the “moof (moof 2)” box, and there is a“tfdt” box in the box. In the “tfdt” box, there is a description ofdecoding time “baseMediaDecodeTime” of the first access unit after the“moof (moof 2)” box. The decoding time “baseMediaDecodeTime” is set tothe same value as of the decoding time “baseMediaDecodeTime” of thetrack TR0 pointed by the extractor.

In addition, there is the “traf” box in the “moof (moof 2)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the display order and decoding order of thebase 60P.

In addition, there is the “tfdt” box in the “moof (moof 2)” box, andthere is a “sgpd” box in the box. In the “sgpd” box, information isarranged associated with the third image data. In the “sgpd” box, thereis a description of the parameter of “grouping_type”. Here,“grouping_type=1” is set, and it is indicated that the grouping type isa temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=2” is set, and it is indicated that the group ID is “2”. Inaddition, “primary_groupID” is described together with “group_id”. Here,since “group_id=2” does not coincide with the value of“primary_groupID”, this group is not identified as the base 60P group.In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “0”, it is indicated that the thirdimage data corresponds to a picture (sample) included in the base 60P.By setting “tlConstantFrameRate” to “1”, it is indicated that the framerate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the third and first image data, and is made tocoincide with “sublayer_level_idc[j−1]” of the element of the SPS (orVPS) described above. Here, “tllevel_idc” is set to “153”. “Tlprofile”indicates the overall profile of the encoded image data of the third andfirst image data, and is made to coincide with“sublayer_profile_idc[j−1]” of the element of the SPS (or VPS) describedabove. Here, “Tlprofile” is set to “7”.

On the other hand, there is a “traf” box in the “moof (moof 3)” box, andthere is a “tfhd” box in the box. There is a description of a track ID“track_id” in the “tfhd” box, and it is indicated that the track is“TR3”. In addition, there is the “traf” box in the “moof (moof 3)” box,and there is a “tfdt” box in the box. In the “tfdt” box, there is adescription of the decoding time “baseMediaDecodeTime” of the firstaccess unit after the “moof (moof 3)” box. The decoding time“baseMediaDecodeTime” is set to the same value as of the decoding time“baseMediaDecodeTime” of the track TR2 pointed by the extractor, andhence is set to the same value as of the decoding time“baseMediaDecodeTime” of the track TR0.

In addition, there is the “traf” box in the “moof (moof 1)” box, andthere is a “trun” box in the box. In the “trun” box, there aredescriptions of parameters of “sample_count” and“sample_composition_time_offset”. With these parameters, values are setof time stamps indicating the display order and decoding order of theenhancement 60P.

In addition, there is the “tfdt” box in the “moof (moof 3)” box, andthere is a “sgpd” box in the box. In the “sgpd” box, information isarranged associated with the fourth image data. In the “sgpd” box, thereis a description of the parameter of “grouping_type”. Here,“grouping_type=1” is set, and it is indicated that the grouping type isa temporal layer group.

In addition, there is a “scif” box in the “sgpd” box, and there is adescription of the parameter of “group_id” in the “scif” box. Here,“group_id=3” is set, and it is indicated that the group ID is “3”. Inaddition, “primary_groupID” is described together with “group_id”. Here,since “group_id=3” does not coincide with the value of“primary_groupID”, this group is not identified as the base 60P group.In addition, there is a “tscl” box in the “sgpd” box. In the “tscl” box,there are descriptions of four parameters of “temporalLayerId”,“tllevel_idc”, “Tlprofile”, and “tlConstantFrameRate”.

By setting “temporalLayerId” to “1”, it is indicated that the fourthimage data corresponds to a picture (sample) included in the enhancement60P. By setting “tlConstantFrameRate” to “1”, it is indicated that theframe rate is constant. “tllevel_idc” indicates the overall level of theencoded image data of the fourth to first image data, and is made tocoincide with “general_level_idc” of the element of the SPS (or VPS)described above. Here, “tllevel_idc” is set to “156”. “Tlprofile”indicates the overall profile of the encoded image data of the fourth tofirst image data, and is made to coincide with “general_profile_idc]” ofthe element of the SPS (or VPS) described above. Here, “Tlprofile” isset to “7”.

FIG. 14 illustrates an example configuration of an MP4 stream (file) inCase 3. In the illustrated example, illustration is omitted of theinitialization segment (IS) and the boxes of “styp”, “sidx”, and “ssix”enclosed by broken line frames in FIG. 4. The illustrated example is anexample of Fragmented MP4. In the MP4 stream, a predetermined number ofMovie Fragments is arranged each including a “moof” box includingcontrol information and a “mdat” box including the body of the mediadata. The “mdat” box includes fragments obtained by fragmentation oftrack data, so that the control information included in the “moof” boxis control information associated with the fragments.

In the MP4 stream including the first video stream including the encodedimage data of the first image data of the Base Layer, in the “mdat” box,the encoded image data (access unit) of the first image data is arrangedfor a predetermined number of pictures, for example, for one GOP. Notethat, the position of each access unit is indicated by information inthe “SIDX” box or “SSIX” box. Each access unit includes NAL units suchas “VPS”, “SPS”, “PPS”, “SEI”, and “SLC”. Note that, “VPS” and “SPS” areinserted into, for example, the access unit at the head of the GOP.

In the MP4 stream including the first video stream, the first videostream is managed with one track, and there is one “moof” box (moof 0)corresponding to the “mdat” block. In the “moof (moof 0)” box, there iscontrol information for management of the encoded image data of thefirst image data in the “mdat” block.

Details in the “moof (moof 0)” box are similar to those of the case ofCase 2 described above, so that description thereof is omitted; however,there is a “tscl” box in the “moof (moof 0)” box. In the “tscl” box,there is a description of “temporalLayerId=0”, for example, and it isindicated that the first image data corresponds to a picture (sample)included in the base 60P. In addition, in the “tscl” box, there is adescription of “tllevel_idc=123”, and it is indicated that the level ofthe encoded image data of the first image data is “level 4.1”. Inaddition, in the “tscl” box, there is a description of“Tlprofile_idc=2”, and it is indicated that the profile of the encodedimage data of the first image data is “Main 10 Profile”.

In addition, in the MP4 stream including the second video streamincluding the encoded image data of the second image data of the BaseLayer, in the “mdat” box, the encoded image data (access unit) of thesecond image data is arranged for a predetermined number of pictures,for example, for one GOP. Note that, the position of each access unit isindicated by information in the “SIDX” box or “SSIX” box. Each accessunit includes NAL units such as “PPS”, “SEI”, and “SLC”.

Note that, for reference from the access unit of the second image datato the access unit of the first image data of another track, anextractor NAL unit is arranged just before all the access units. Forexample, in a case where the access unit of “2” is decoded, it isnecessary to refer to the access unit of “0”, and in this case, adecoding result of the access unit of “0” is copied to the extractorarranged just before the access unit of “2” and used.

In the MP4 stream including the second video stream, the second videostream is managed with one track, and there is one “moof” box (moof 1)corresponding to the “mdat” block. In the “moof (moof 1)” box, there iscontrol information for management of the encoded image data of thesecond image data in the “mdat” block.

Details in the “moof (moof 1)” box are similar to those of the case ofCase 2 described above, so that description thereof is omitted; however,there is a “tscl” box in the “moof (moof 1)” box. In the “tscl” box,there is a description of “temporalLayerId=1”, for example, and it isindicated that the first image data corresponds to a picture (sample)included in the enhancement 60P. In addition, in the “tscl” box, thereis a description of “tllevel_idc=150”, and it is indicated that theoverall level of the encoded image data of the second and first imagedata is “level 5”. In addition, in the “tscl” box, there is adescription of “Tlprofile_idc=2”, and it is indicated that the overallprofile of the encoded image data of the second and first image data is“Main 10 Profile”.

Within the layer, a decoding time stamp is given so that the decodingorder of 120P in the Base Layer becomes 0→2→4→6→ . . . . With thisdecoding time stamp, the decoding order of 60P becomes 0→4→ . . . . Thatis, the base 60P and enhancement 60P are set so that the time stampvalues are alternated in both the display order and the decoding order.

In addition, in the MP4 stream including the third video streamincluding the encoded image data of the third image data of the ScalableLayer, in the “mdat” box, the encoded image data (access unit) of thethird image data is arranged for a predetermined number of pictures, forexample, for one GOP. Note that, the position of each access unit isindicated by information in the “SIDX” box or “SSIX” box. Each accessunit includes NAL units such as “PPS”, “SEI”, and “SLC”.

Note that, for reference from the Scalable Layer to the Base Layer, anextractor NAL unit is arranged just before all the access units. Forexample, in a case where the access unit of “1” is decoded, it isnecessary to refer to the access unit of “0”, and in this case, adecoding result of the access unit of “0” is copied to the extractorarranged just before the access unit of “1” and used.

In the MP4 stream including the third video stream, the third videostream is managed with one track, and there is one “moof” box (moof 2)corresponding to the “mdat” block. In the “moof (moof 2)” box, there iscontrol information for management of the encoded image data of thethird image data in the “mdat” block.

Details in the “moof (moof 2)” box are similar to those of the case ofCase 2 described above, so that description thereof is omitted; however,there is a “tscl” box in the “moof (moof 2)” box. In the “tscl” box,there is a description of “temporalLayerId=0”, for example, and it isindicated that the third image data corresponds to a picture (sample)included in the base 60P. In addition, in the “tscl” box, there is adescription of “tllevel_idc=153”, and it is indicated that the overalllevel of the encoded image data of the third and first image data is“level 5.1”. In addition, in the “tscl” box, there is a description of“Tlprofile_idc=7”, and it is indicated that the overall profile of theencoded image data of the third and first image data is “Scalable Main10 Profile”.

In addition, in the MP4 stream including the fourth video streamincluding the encoded image data of the fourth image data of theScalable Layer, in the “mdat” box, the encoded image data (access unit)of the fourth image data is arranged for a predetermined number ofpictures, for example, for one GOP. Note that, the position of eachaccess unit is indicated by information in the “SIDX” box or “SSIX” box.Each access unit includes NAL units such as “PPS”, “SEI”, and “SLC”.

Note that, for reference from the Scalable Layer to the Base Layer andadditionally for reference from the access unit of the fourth image datato the access unit of the third image data of another track, anextractor NAL unit is arranged just before all the access units. Forexample, in a case where the access unit of “3” is decoded, it isnecessary to refer to the access units of “2” and “1”, and in this case,decoding results of the access units of “2” and “1” are copied to thetwo extractors arranged just before the access units of “2” and “1” andused.

In the MP4 stream including the fourth video stream, the fourth videostream is managed with one track, and there is one “moof” box (moof 3)corresponding to the “mdat” block. In the “moof (moof 3)” box, there iscontrol information for management of the encoded image data of thefourth image data in the “mdat” block.

Details in the “moof (moof 3)” box are similar to those of the case ofCase 2 described above, so that description thereof is omitted; however,there is a “tscl” box in the “moof (moof 3)” box. In the “tscl” box,there is a description of “temporalLayerId=1”, for example, and it isindicated that the fourth image data corresponds to a picture (sample)included in the enhancement 60P. In addition, in the “tscl” box, thereis a description of “tllevel_idc=156”, and it is indicated that theoverall level of the encoded image data of the fourth to first imagedata is “level 5.2”. In addition, in the “tscl” box, there is adescription of “Tlprofile_idc=7”, and it is indicated that the overallprofile of the encoded image data of the fourth to first image data is“Scalable Main 10 Profile”.

Note that, in the example of FIG. 14, the transmission order of eachsample (picture) is set in the order of 0→1→2→3→4→5→ . . . . With thissetting, it is possible to minimize the delay from reception to display.

Here, the parameters will be further described of “sample_count” and“sample_composition_time_offset” for setting the value of the time stampindicating the display order and decoding order of the base 60P andenhancement 60P. “baseMediaDecodeTime” in the “tfdt” box represents thedecoding time stamp of the first sample (picture) of the fragment. Thedecoding time of each subsequent sample is described by “sample_count”in the “trun” box. In addition, the display time stamp of each sample isrepresented by “sample_composition_time_offset” indicating an offsetfrom “sample_count”.

In the Base Layer of FIG. 7, “sample_count” of “0” coincides with“baseMediaDecodeTime”, and then “sample_count” of “2” and “4” are valuessequentially increased one by one in units of 120 Hz, respectively. Thisindicates that the decoding time of the sample of “2” that is the sampleof the enhancement 60P is sandwiched between the decoding times of thetwo samples of “0” and “4” that are samples of the base 60P.

In addition, in the Scalable Layer, the decoding time (=“sample_count”)of the extractor of “1” indicating inter-layer prediction is the samevalue as of the decoding time of the sample of “0”. “sample_count” of“1” has the same value as the immediately preceding extractor andindicates that there is no time offset. The extractor of “3” is arrangedin a case where “2” is referenced, and its “sample_count” has the samevalue as of “2”. In a case where the referent of the sample of “3” is“1”, the value increased by 1 to “sample_count” of “1” is set to thevalue of “sample_count” of “3”.

In this way, “sample_count” corresponding to the decoding time is givenwith an accuracy of 120 Hz. A receiver that decodes the base 60P of theBase Layer transfers only the sample belonging to the base 60P group, inevery other one, to the decoder.

In both FIGS. 11 and 14, “sample_count” of the extractor of “2” withinthe Base Layer has the same value as of “sample_count” of “0”.“sample_count” of “2” is a value increased by 1 to “sample_count” of theimmediately preceding extractor. The value of “sample_count” of “4” is avalue further increased by 1 to “sample_count” of “2”. Subsequently,this is performed similarly. In this way, “sample_count” correspondingto the decoding time is given with an accuracy of 120 Hz.

In the Scalable Layer, the extractor of “1” represents inter-layerreference, its “sample_count” has the same value as of “0”, and“sample_count” of “1” has the same value as of the immediately precedingextractor. In the extractor of “3”, in a case where another track withinthe Scalable Layer is referenced, its “sample_count” is the same as of“1”, and alternatively, in a case where the value of “2” of the BaseLayer is referenced, its “sample_count” is the same as of “2”. In eithercase, the value of “sample_count” of “3” has the same value as of “2”.

The extractor of “5” represents inter-layer reference, and its“sample_count” has the same value as of “sample_count” of “4”.“Sample_count” of “5” has the same value as of “4”. As described above,also in the Scalable Layer, the decoding time of the sample of “3” thatis the sample of the enhancement 60P is sandwiched between the decodingtimes of the two samples of “1” and “5” that are samples of the base60P. A receiver that decodes 60P of the Scalable Layer transfers“sample_count” of the sample within the layer, in every other one, tothe decoder, for only the sample belonging to the base 60P group.

FIG. 15 illustrates a description example of the MPD file in the case oftransmission of a two-stream configuration (in the cases of Case 1 andCase 2). Here, for simplicity of description, an example is shown inwhich only the information associated with the video stream isdescribed; however, information associated with other media streams ofthe video stream is also described, actually. FIG. 16 illustrates“Value” semantics of “SupplementaryDescriptor”.

By the description of “<AdaptationSet mimeType=“video/mp4”codecs=“hev1.xx.xx.L150,xx, hev1.yy.yy.L156,yy””, it is indicated thatthere is an AdaptationSet for a video stream, the video stream issupplied in an MP4 file structure, and there are HEVC encoded image dataof a level of 150, and a level of 156.

By the description of “<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:highdynamicrange” value=“HDR”/>”, it isindicated that the current stream is an HDR stream. Note that, “1” maybe described instead of “HDR” to indicate that it is an HDR stream. Notethat, in the case of indicating that it is an SDR stream, “SDR” or “0”is described.

By the description of “<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:transferfunction” value=“TFtype”/>”, theelectro-optical and photoelectric conversion characteristics (TFcharacteristic) are indicated. For example, in the case of “BT.709-5Transfer Function”, “bt709” or “1” is described in the “TFtype” part. Inaddition, for example, in the case of “10 bit BT.2020 TransferFunction”, “bt2020-10” or “14” is described in the “TFtype” part. Inaddition, for example, in the case of “SMPTE 2084 Transfer Function”,“st2084” or “16” is described in the “TFtype” part. In addition, forexample, in the case of “ARIB STD B-67 Transfer Function”, “arib-b67” or“18” is described in the “TFtype” part.

By the description of “<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:xycolourprimaries” value=“ColorGamut”/>”,the color space is indicated. For example, in the case of “BT.709-5”,“bt709” or “1” is described in the “ColorGamut” part. In addition, forexample, in the case of “BT.2020”, “bt2020” or “9” is described in the“ColorGamut” part. In addition, for example, in the case of “SMPTE 428or XYZ”, “st428” or “10” is described in the part of “ColorGamut”.

In the MPD file, there is a first Representation corresponding to thefirst video stream including the encoded image data of the first andsecond image data, and there is a second Representation corresponding tothe second video stream including the third and fourth image data. Inaddition, in the Representation of the first video stream, there areSubRepresentations corresponding to the encoded image data of the firstand second image data, respectively. In addition, in the Representationof the second video stream, there are SubRepresentations correspondingto the encoded image data of the third and fourth image data,respectively.

By the description of “<BaseURL>videostreamBase.mp4</BaseURL>”, thelocation of the first video stream is indicated as“videostreamBase.mp4”. In the SubRepresentation corresponding to theencoded image data of the first image data in the Representation of thefirst video stream, there are descriptions of “width=“1920”height=“1080” frameRate=“60””, “codecs=“hev1.xx.xx.L123,xx””, and“level=“0””. With the descriptions, it is indicated that a 2K 60P streamis achieved, level “0” is given as tag information, and the level of theencoded image data of the first image data is “123”.

In the SubRepresentation corresponding to the encoded image data of thesecond image data in the Representation of the first video stream, thereare descriptions of “width=“1920” height=“1080” frameRate=“120””,“codecs=“hev1.xx.xx.L150,xx””, “level=“1”, and “dependencyLevel=“0””.With the descriptions, it is indicated that a 2K 120P stream is achievedon the encoded image data of the first image data by enhancement, thelevel “1” is given as tag information, and the overall level of theencoded image data of the second and first image data is “150”.

In addition, by the description of“<BaseURL>video-bitstreamScalable.mp4</BaseURL>”, the location of thesecond video stream is indicated as “video-bitstreamScalable.mp4”. Inthe SubRepresentation corresponding to the encoded image data of thethird image data in the Representation of the second video stream, thereare descriptions of “width=“3840” height=“2160” frameRate=“60””,“codecs=“hev1.yy.yy.L153, yy”, “level=“2””, and “dependencyLevel=“0””.With the descriptions, it is indicated that a 4K 60P stream is achievedon the encoded image data of the first image data by enhancement, thelevel “2” is given as tag information, and the overall level of theencoded image data of the third and first image data is “153”.

In the SubRepresentation corresponding to the encoded image data of thefourth image data in the Representation of the second video stream,there are descriptions of “width=“3840” height=“2160” frameRate=“120””,“codecs=“hev1.yy.yy.L156,yy””, “level=“3””, and “dependencyLevel=“0”,“1”, “2””. With the descriptions, it is indicated that a 2K 120P streamis achieved on the encoded image data of the first image data byenhancement and a 4K 120P stream is achieved by adding an enhancementcomponent on the stream, the level “3” is given as tag information, andthe overall level of the encoded image data of the fourth to first imagedata is “156”.

FIG. 17 illustrates a description example of the MPD file in the case oftransmission of a four-stream configuration (in the case of Case 2).Here, for simplicity of description, an example is shown in which onlythe information associated with the video stream is described; however,information associated with other media streams of the video stream isalso described, actually.

By description of “<AdaptationSet mimeType=“video/mp4”codecs=“hev1.xx.xx.L123,xx, hev1.xx.xx.L150,xx, hev1.yy.yy.L153,yy,hev1.yy.yy.L156,yy””, it is indicated that there is an AdaptationSet fora video stream, the video stream is supplied in an MP4 file structure,and there are HEVC encoded image data of a level of 123, of a level of150, a level of 153, and a level of 156.

Since descriptions of “<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:highdynamicrange” value=“HDR”/>”,“<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:transferfunction” value=“EOTFtype”/>”, and“<SupplementaryDescriptorschemeIdUri=“urn:brdcst:video:xycolourprimaries” value=“ColorGamut”/>”are the same as those of the example in FIG. 15, the description thereofwill be omitted.

In the MPD file, there are first, second third, and fourthRepresentations respectively corresponding to the first, second, third,and fourth video streams including the encoded image data of therespective first, second, third and fourth image data.

In the Representation of the first video stream, there are descriptionsof “width=“1920” height=“1080” frameRate=“60””,“codecs=“hev1.xx.xx.L123,xx””, and “level=“0””. With the descriptions,it is indicated that a 2K 60P stream is achieved, level “0” is given astag information, and the level of the encoded image data of the firstimage data is “123”. By the description of“<BaseURL>video-base1subbitstream.mp4</BaseURL>”, the location of thefirst video stream is indicated as “video-base1subbitstream.mp4”.

In the Representation of the second video stream, there are descriptionsof “width=“1920” height=“1080” frameRate=“120””,“codecs=“hev1.xx.xx.L150,xx””, “level=“1””, and “dependencyLevel=“0””.With the descriptions, it is indicated that a 2K 120P stream is achievedon the encoded image data of the first image data by enhancement, thelevel “1” is given as tag information, and the overall level of theencoded image data of the second and first image data is “150”. By thedescription of “<BaseURL>video-base2subbitstream.mp4</BaseURL>”, thelocation of the second video stream is indicated as“video-base2subbitstream.mp4”.

In the Representation of the third video stream, there are descriptionsof “width=“3840” height=“2160” frameRate=“60””,“codecs=“hev1.yy.yy.L153,yy””, “level=“2””, and “dependencyLevel=“0””.With the descriptions, it is indicated that a 4K 60P stream is achievedon the encoded image data of the first image data by enhancement, thelevel “2” is given as tag information, and the overall level of theencoded image data of the third and first image data is “153”. By thedescription of “<BaseURL>video-e1subbitstream.mp4</BaseURL>”, thelocation of the third video stream is indicated as“video-e1subbitstream.mp4”.

In the Representation of the fourth video stream, there are descriptionsof “width=“3840” height=“2160” frameRate=“120””,“codecs=“hev1.yy.yy.L156,yy””, “level=“3””, and “dependencyLevel=“0”,“1”, “2””. With the descriptions, it is indicated that a 2K 120P streamis achieved on the encoded image data of the first image data byenhancement and a 4K 120P stream is achieved by adding an enhancementcomponent on the stream, the level “3” is given as tag information, andthe overall level of the encoded image data of the fourth to first imagedata is “156”. By the description of“<BaseURL>video-e2subset.mp4</BaseURL>”, the location of the fourthvideo stream is indicated as “video-e2subset.mp4”.

“Example Configuration of Service Transmission System”

FIG. 18 illustrates an example configuration of the service transmissionsystem 100. The service transmission system 100 includes a control unit101, a high-dynamic-range (HDR) photoelectric conversion unit 102, anRGB/YCbCr conversion unit 103, the video encoder 104, a containerencoder 105, and a transmission unit 106.

The control unit 101 includes a Central Processing Unit (CPU), andcontrols operation of each unit of the service transmission system 100on the basis of a control program. The HDR photoelectric conversion unit102 obtains HDR transmission image data V1 by performing photoelectricconversion by applying the HDR photoelectric conversion characteristicto high-frame-rate ultra-high-definition (for example, 4K 120P) andhigh-dynamic-range (HDR) image data (video data) Vh. The HDRtransmission video data V1 is a video material produced as an image withan HDR OETF. For example, a characteristic of STD-B67 (Hybrid Log-Gamma:HLG), a characteristic of ST2084 (Perceptual Quantizer curve: PQ curve),or the like is applied as the HDR photoelectric conversioncharacteristic.

FIG. 19 illustrates examples of photoelectric conversion characteristicsof a standard dynamic range (SDR) and a high dynamic range (HDR). In thefigure, the horizontal axis indicates an input luminance level and thevertical axis indicates a transmission code value. The broken lineindicates an SDR photoelectric conversion characteristic (BT.709: gammacharacteristic). In the SDR photoelectric conversion characteristic,when the input luminance level is an SDR characteristic representationlimit luminance SL, the transmission code value is a peak level MP.Here, SL is 100 cd/m².

The solid line b indicates the characteristic of STD-B67 (HLG) as theHDR photoelectric conversion characteristic. The one-dot chain line cindicates the characteristic of ST2084 (PQ curve) as the HDRphotoelectric conversion characteristic. In the HDR photoelectricconversion characteristics, when the input luminance level is a peakluminance PL, the transmission code value is a peak level MP.

The characteristic of STD-B67 (HLG) includes a compatible area with theSDR photoelectric conversion characteristic (BT.709: gammacharacteristic). That is, curves of the two characteristics coincidewith each other from the input luminance level of zero to acompatibility limit value of both characteristics. When the inputluminance level is the compatibility limit value, the transmission codevalue is a compatibility level SP. The characteristic of ST2084 (PQcurve) is a curve of a quantization step that corresponds to highluminance and is said to be compatible with human visualcharacteristics.

Referring back to FIG. 18, the RGB/YCbCr conversion unit 103 convertsthe HDR transmission video data V1 obtained by the HDR photoelectricconversion unit 102, from the RGB domain to the YCbCr (luminance andchrominance) domain. Note that, these color space domains are notlimited to the RGB domain, and the luminance and chrominance domain isnot limited to YCbCr.

The video encoder 104 applies encoding, for example, MPEG 4-AVC or HEVC,to the HDR transmission video data V1 converted to the YCbCr domain toobtain encoded image data, and generates a predetermined number of videostreams including the encoded image data.

That is, in a case where transmission is performed of Case 1 and Case 2,the first video stream including the encoded image data of the first andsecond image data and the second video stream including the encodedimage data of the third and fourth image data are generated (See FIGS.6, 7, and 11). On the other hand, in a case where transmission isperformed of Case 3, the first video stream including the encoded imagedata of the first image data, the second video stream including theencoded image data of the second image data, the third video streamincluding the encoded image data of the third image data, and the fourthvideo stream including the encoded image data of the fourth image dataare generated (see FIGS. 6 and 14).

At this time, the video encoder 104 inserts conversion characteristicinformation (transferfunction) indicating a photoelectric conversioncharacteristic of the HDR transmission image data V1 or anelectro-optical conversion characteristic corresponding to thephotoelectric conversion characteristic, into an area of video usabilityinformation (VUI) of an SPS NAL unit of an access unit (AU). Note that,in a case where the photoelectric conversion characteristic of the HDRtransmission image data V1 is STD-B67 (HLG), conversion characteristicinformation indicating BT.709 (gamma characteristic) is inserted intothe area of the VUI. In this case, the conversion characteristicinformation indicating STD-B67 (HLG) is arranged in a newly definedtransfer function SEI message (transfer_function SEI message) describedlater that is inserted into the “SEIs” part of the access unit (AU).

In addition, in a case where the characteristic of ST2084 (PQ curve) isapplied as the HDR photoelectric conversion characteristic in the HDRphotoelectric conversion unit 102 described above, the video encoder 104inserts a newly defined dynamic range conversion SEI message(Dynamic_range_conv SEI message) described later that includesconversion information of dynamic range conversion, into the “SEIs” partof the access unit (AU). The conversion information is conversioninformation for conversion of the value of the conversion data by thecharacteristic of ST2084 (PQ curve) into the value of the conversiondata by the SDR photoelectric conversion characteristic.

With reference to FIG. 20, the conversion information of the dynamicrange conversion will be further described. The solid line a indicatesan example of an SDR OETF curve indicating the SDR photoelectricconversion characteristic. The solid line b indicates an example of thecharacteristic of the ST2084 (PQ curve) as an HDR OETF curve. Thehorizontal axis indicates an input luminance level, P1 indicates aninput luminance level corresponding to the SDR peak level, and P2indicates an input luminance level corresponding to the HDR maximumlevel.

In addition, the vertical axis indicates a transmission code value or arelative value of a normalized encoding level. A relative maximum levelM indicates the HDR maximum level and the SDR maximum level. A referencelevel G indicates a transmission level of the HDR OETF at the inputluminance level P1 corresponding to the SDR maximum level, which means aso-called reference white level, and a range higher than the level isused for sparkle representation specific to the HDR. A branch level Bindicates a level at which the SDR OETF curve and the HDR OETF curvebranch from the same trajectory. Pf indicates an input luminance levelcorresponding to the branch level. Note that, the branch level B can bean arbitrary value of greater than or equal to 0. Note that, in a casewhere the branch level is not specified, it is approximated by acorresponding distribution operation method or by obtaining with a ratiofrom the whole on the reception side.

The conversion information of the dynamic range conversion isinformation for conversion from the branch level B to the relativemaximum level M in the HDR transmission image data, into the value ofthe conversion data by the SDR photoelectric conversion characteristic,and is a conversion coefficient, or a conversion table. In a case wherethe information is given by the conversion table, the dynamic rangeconversion is performed by referring to the conversion table. On theother hand, in a case where the information is given by the conversioncoefficient, the dynamic range conversion is performed by calculationusing the conversion coefficient. For example, when the conversioncoefficient is C, conversion can be performed on the input data from thebranch level B to the relative maximum level G, by the followingequation (1).Output data=branch levelB+(input data−branch levelB)*C  (1)

FIG. 21 illustrates an access unit at the head of a Group Of Pictures(GOP) in a case where an encoding method is HEVC. In the case of theHEVC encoding method, an SEI message group for decoding “Prefix_SEIs” isarranged before slices in which pixel data is encoded, and after theslices, an SEI message group for display “Suffix_SEIs” is arranged. Thetransfer function SEI message and the dynamic range conversion SEImessage are arranged as the SEI message group “Suffix_SEIs”, forexample, as illustrated in the figure.

FIG. 22(a) illustrates an example structure (Syntax) of the transferfunction SEI message. FIG. 22(b) illustrates details (Semantics) of maininformation in the example structure. The 8-bit field of“transferfunction” indicates a photoelectric conversion characteristicof the transmission video data V1 or an electro-optical conversioncharacteristic corresponding to the photoelectric conversioncharacteristic. In a case where the value of this element differs fromthe value of “transferfunction” of the VUI, replacement is performedwith the value of this element.

For example, “1” indicates “BT.709-5 Transfer Function (SDR)”, “14”indicates “10 bit BT.2020 Transfer Function (SDR)”, “16” indicates“SMPTE 2084 Transfer Function (HDR1)”, and “18” indicates “ARIB STD B-67Transfer Function (HDR2)”.

The 16-bit field of “peak luminance” indicates the maximum luminancelevel. The maximum luminance level indicates the maximum luminance levelof a content, for example, within a program or a scene. In the receptionside, this value can be used as a reference value when a display imagesuitable for display capability is created. The 8-bit field of“color_space” indicates color space information.

FIG. 23 illustrates an example structure (Syntax) of the dynamic rangeconversion SEI message. FIG. 24 illustrates details (Semantics) of maininformation in the example structure. The 1-bit flag information of“Dynamic_range_conv_cancel_flag” indicates whether a message of“Dynamic_range_conv” is to be refreshed. “0” indicates that the messageof “Dynamic_range_conv” is to be refreshed. “1” indicates that themessage of “Dynamic_range_conv” is not to be refreshed, that is, theprevious message is maintained as it is.

When “Dynamic_range_conv_cancel_flag” is “0”, the following fieldsexist. The 8-bit field of “coded_data_bit_depth” indicates the encodedpixel bit depth (the bit depth of the transmission code value). The14-bit field of “reference_level” indicates a reference luminance levelvalue, that is, the reference level G (see FIG. 20). The 1-bit flaginformation of “ratio_conversion_flag” indicates that simple conversionis performed, that is, the conversion coefficient exists. The 1-bit flaginformation of “conversion_table_flag” indicates that the conversion isbased on the conversion table, that is, conversion table informationexists. The 16-bit field of “branch_level” indicates the branch level B(see FIG. 20).

When “ratio_conversion_flag” is “1”, the 8-bit field of“level_conversion_ratio” exists. The field indicates the conversioncoefficient (ratio of level conversion). When “conversion_table_flag” is“1”, the 8-bit field of “table_size” exists. The field indicates thenumber of inputs in the conversion table. Then, 16-bit fields of“level_R [i]”, “level_G [i]”, and “level_B [i]” exist for the number ofinputs. The field of “level_R [i]” indicates a value after conversion ofa red component (Red component). The field of “level_G [i]” indicates avalue after conversion of a green component (Red component). The fieldof “level_B [i]” indicates a value after conversion of a blue component(Red component).

Note that, when the encoded pixel bit depth is 8 bits, a value existscorresponding to each value of the input data. However, when the encodedpixel bit depth is 10 bits, 12 bits, or the like, only valuescorresponding to respective values of the upper 8 bits of the input dataexist. In this case, when the conversion table is used in the receptionside, an interpolation value is used for values of the remaining lowerbits.

Referring back to FIG. 18, the container encoder 105 generates acontainer including a predetermined number of video streams VS generatedby the video encoder 104, here, an MP4 stream, as a distribution streamSTM.

That is, in a case where transmission is performed of Case 1 and Case 2,an MP4 stream including the first video stream including the encodedimage data of the first and second image data and an MP4 streamincluding the second video stream including the encoded image data ofthe third and fourth image data are generated (see FIGS. 6, 7, and 11).

On the other hand, in a case where transmission is performed of Case 3,an MP4 stream including the first video stream including the encodedimage data of the first image data, an MP4 stream including the secondvideo stream including the encoded image data of the second image data,an MP4 stream including the third video stream including the encodedimage data of the third image data, and an MP4 stream including thefourth video stream including the encoded image data of the fourth imagedata are generated (see FIGS. 6 and 14).

The transmission unit 106 transmits the MP4 distribution stream STMobtained by the container encoder 105 on a broadcast wave or a networkpacket to the service receiver 200.

Operation of the service transmission system 100 illustrated in FIG. 18will be briefly described. The high-frame-rate ultra-high-definition(for example, 4K 120P) and high-dynamic-range (HDR) image data (videodata) Vh is supplied to the HDR photoelectric conversion unit 102. Inthe HDR photoelectric conversion unit 102, photoelectric conversion isapplied to the HDR video data Vh by the HDR photoelectric conversioncharacteristic, and HDR transmission video data is obtained as a videomaterial produced as an image with an HDR OETF. For example, thecharacteristic of STD-B67 (HLG), the characteristic of ST2084 (PQcurve), or the like is applied as the HDR photoelectric conversioncharacteristic.

The HDR transmission video data V1 obtained by the HDR photoelectricconversion unit 102 is converted from the RGB domain to the YCbCr domainby the RGB/YCbCr conversion unit 103, and then supplied to the videoencoder 104. In the video encoder 104, encoding, for example, MPEG 4-AVCor HEVC is applied to the HDR transmission video data V1 converted tothe YCbCr domain and encoded image data is obtained, and a predeterminednumber of video streams is generated including the encoded image data.

That is, in a case where transmission is performed of Case 1 and Case 2,the first video stream including the encoded image data of the first andsecond image data and the second video stream including the encodedimage data of the third and fourth image data are generated (See FIGS.6, 7, and 11). On the other hand, in a case where transmission isperformed of Case 3, the first video stream including the encoded imagedata of the first image data, the second video stream including theencoded image data of the second image data, the third video streamincluding the encoded image data of the third image data, and the fourthvideo stream including the encoded image data of the fourth image dataare generated (see FIGS. 6 and 14).

At this time, in the video encoder 104, the conversion characteristicinformation (transferfunction) indicating the photoelectric conversioncharacteristic of the HDR transmission video data V1 or theelectro-optical conversion characteristic corresponding to thephotoelectric conversion characteristic is inserted into the area of theVUI of the SPS NAL unit of the access unit (AU). Note that, in a casewhere the photoelectric conversion characteristic of the HDRtransmission video data V1 is STD-B67 (HLG), the conversioncharacteristic information indicating BT.709 (gamma characteristic) isinserted into the area of the VUI. In this case, the conversioncharacteristic information indicating STD-B67 (HLG) is arranged in thetransfer function SEI message (see FIG. 22) inserted into the “SEIs”part of the access unit (AU).

In addition, at this time, in a case where the characteristic of ST2084(PQ curve) is applied as the HDR photoelectric conversion characteristicin the HDR photoelectric conversion unit 102, in the video encoder 104,dynamic range conversion SEI message (see FIG. 23) including theconversion information of dynamic range conversion is inserted into the“SEIs” part of the access unit (AU). The conversion information isconversion information for conversion of the value of the conversiondata by the characteristic of ST2084 (PQ curve) into the value of theconversion data by the SDR photoelectric conversion characteristic.

The predetermined number of video streams VS generated by the videoencoder 104 is supplied to the container encoder 105. In the containerencoder 105, the container including the predetermined number of videostreams VS, here, the MP4 stream, is generated as the distributionstream STM.

That is, in a case where transmission is performed of Case 1 and Case 2,an MP4 stream including the first video stream including the encodedimage data of the first and second image data and an MP4 streamincluding the second video stream including the encoded image data ofthe third and fourth image data are generated (see FIGS. 6, 7, and 11).

On the other hand, in a case where transmission is performed of Case 3,an MP4 stream including the first video stream including the encodedimage data of the first image data, an MP4 stream including the secondvideo stream including the encoded image data of the second image data,an MP4 stream including the third video stream including the encodedimage data of the third image data, and an MP4 stream including thefourth video stream including the encoded image data of the fourth imagedata are generated (see FIGS. 6 and 14).

The MP4 stream generated as the distribution stream STM by the containerencoder 105 is supplied to the transmission unit 106. In thetransmission unit 106, the MP4 distribution stream STM obtained by thecontainer encoder 105 is transmitted on the broadcast wave or thenetwork packet to the service receiver 200.

“Example Configuration of Service Receiver”

FIG. 25 illustrates an example configuration of the service receiver200. The service receiver 200 includes a control unit 201, a receptionunit 202, a container decoder 203, a video decoder 204, a YCbCr/RGBconversion unit 205, an HDR electro-optical conversion unit 206, and anSDR electro-optical conversion unit 207.

The control unit 201 includes a Central Processing Unit (CPU), andcontrols operation of each unit of the service receiver 200 on the basisof a control program. The reception unit 202 receives the MP4distribution stream STM transmitted on the broadcast wave or the networkpacket from the service transmission system 100.

Under the control of the control unit 201, depending on the decodingcapability of the receiver 200, the container decoder (multiplexer) 103selectively extracts the encoded image data of the required image data,on the basis of information of the “moof” block and the like, from theMP4 distribution stream STM received by the reception unit 202, andtransmits the encoded image data to the video decoder 204.

For example, when the receiver 200 has a decoding capability capable ofprocessing high-frame-rate ultra-high-definition image data, thecontainer decoder 203 extracts encoded image data of all the first tofourth image data, and transmits the encoded image data to the videodecoder 204. In addition, for example, when the receiver 200 has adecoding capability capable of processing base-frame-rateultra-high-definition image data, the container decoder 203 extractsencoded image data of the first and third image data, and transmits theencoded image data to the video decoder 204.

In addition, for example, when the receiver 200 has a decodingcapability capable of processing high-frame-rate high-definition imagedata, the container decoder 203 extracts encoded image data of the firstand second image data, and transmits the encoded image data to the videodecoder 204. In addition, for example, when the receiver 200 has adecoding capability capable of processing base-frame-ratehigh-definition image data, the container decoder 203 extracts encodedimage data of the first image data, and transmits the encoded image datato the video decoder 204.

For example, the container decoder 203 checks a level value (tlevel_idc)inserted into the container, compares the level value with the decodingcapability of the video decoder 204, and determines whether or notreception is possible. At that time, a value corresponding to complexity(general_level_idc) of the entire stream in the received video stream isdetected from “tlevel_idc” in the “moof” block.

Then, in a case where the detected value is higher than the decodingcapability of the receiver, the container decoder 203 checks“tlevel_idc” in the “moof” block corresponding to a value of anotherelement (sublayer_level_idc) in the video stream, determines whetherdecoding is possible within the applicable range, and transfers theencoded image data of the corresponding image data to the video decoder204.

On the other hand, a value corresponding to the complexity(general_level_idc) of the entire stream in the received video stream isdetected from “tlevel_idc” in the “moof” block, and in a case where thevalue corresponds to the decoding capability of the receiver, thecontainer decoder 203 transfers the encoded image data of all the imagedata included in the received video stream to the video decoder 204 inthe order of decoding time stamps.

The video decoder 204 applies decoding processing to the encoded imagedata selectively extracted by the container decoder 203 to obtain HDRtransmission video data V1′. For example, when the receiver 200 has adecoding capability capable of processing high-frame-rateultra-high-definition image data, the HDR transmission video data V1′becomes image data for display of a high-frame-rateultra-high-definition image. In addition, for example, when the receiver200 has a decoding capability capable of processing base-frame-rateultra-high-definition image data, the HDR transmission video data V1′becomes image data for display of a base-frame-rateultra-high-definition image.

In addition, for example, when the receiver 200 has a decodingcapability capable of processing high-frame-rate high-definition imagedata, the HDR transmission video data V1′ becomes image data for displayof a high-frame-rate high-definition image. In addition, for example,when the receiver 200 has a decoding capability capable of processingbase-frame-rate high-definition image data, the HDR transmission videodata V1′ becomes image data for display of a base-frame-ratehigh-definition image.

In addition, the video decoder 204 extracts the parameter set and theSEI message inserted into the encoded image data selectively extractedby the container decoder 203, and transmits them to the control unit201.

The extracted information also includes conversion characteristicinformation (transferfunction) indicating the photoelectric conversioncharacteristic of the transmission video data V1 inserted into the areaof the VUI of the SPS NAL unit of the above-described access unit or theelectro-optical conversion characteristic corresponding to thephotoelectric conversion characteristic, and the transfer function SEImessage (see FIG. 22). With the information, the control unit 201recognizes the HDR photoelectric conversion characteristic applied tothe HDR transmission video data V1′.

In addition, when the HDR photoelectric conversion characteristicapplied to the HDR transmission video data V1′ is the characteristic ofST2084 (PQ curve), the extracted information also includes the dynamicrange conversion SEI message (see FIG. 23). With the information, thecontrol unit 201 recognizes dynamic range conversion information(conversion table, conversion coefficient).

The YCbCr/RGB conversion unit 205 converts the HDR transmission videodata V1′ obtained by the video decoder 204 from the YCbCr (luminance andchrominance) domain to the RGB domain. The HDR photoelectric conversionunit 206 obtains display video data Vhd for display of an HDR image byapplying the HDR electro-optical conversion characteristic to the HDRtransmission video data V1′ converted to the RGB domain. In this case,the control unit 201 sets, for the HDR photoelectric conversion unit206, the HDR electro-optical conversion characteristic recognized fromthe VUI or the transfer function SEI message, that is, the HDRelectro-optical conversion characteristic corresponding to the HDRphotoelectric conversion characteristic applied in the transmissionside.

The SDR photoelectric conversion unit 207 obtains display video data Vsdfor display of the SDR image by applying the SDR electro-opticalconversion characteristic to the HDR transmission video data V1′converted to the RGB domain. Here, when the HDR photoelectric conversioncharacteristic applied to the HDR transmission video data V1′ is thecharacteristic of STD-B67 (HLG), the SDR photoelectric conversion unit207 obtains the display video data Vsd for display of the SDR image bydirectly applying the SDR electro-optical conversion characteristic tothe HDR transmission video data V1′.

On the other hand, when the HDR photoelectric conversion characteristicapplied to the HDR transmission video data V1′ is the characteristic ofST2084 (PQ curve), the SDR photoelectric conversion unit 207 obtains SDRtransmission image data by performing, on the HDR transmission videodata V1′, dynamic range conversion on the basis of the dynamic rangeconversion information (conversion table, conversion coefficient), andobtains the display video data Vsd for display of the SDR image byapplying the SDR electro-optical conversion characteristic to the SDRtransmission image data.

With reference to FIG. 26, an example of the dynamic range conversionbased on the dynamic range conversion information will be described. Thevertical axis indicates an output luminance level, which corresponds tothe horizontal axis in FIG. 20. In addition, the horizontal axisindicates a transmission code value, which corresponds to the verticalaxis in FIG. 20. The solid line a is an SDR EOTF curve indicating theSDR electro-optical conversion characteristic. The SDR EOTF curvecorresponds to the SDR OETF curve indicated by the solid line in FIG.20. The solid line b is an HDR EOTF curve indicating the HDRelectro-optical conversion characteristic. The HDR EOTF curvecorresponds to the characteristic of ST2084 (PQ curve) as the HDR OETFcurve indicated by the solid line b in FIG. 20. Note that, P1′ indicatesan output luminance level corresponding to a predetermined level H lowerthan the reference level G.

In the dynamic range conversion, input data up to the predeterminedlevel H lower than the reference level G among the HDR transmissionvideo data V1′ is converted so as to coincide with the value of theconversion data by the SDR photoelectric conversion characteristic.Input data less than branch level B is set to output data as it is.

In addition, for input data from the level H to the level M, dynamicrange level conversion is performed on the basis of a tone mappingcharacteristic TM indicated by the one-dot chain line. In this case, forexample, the level H is converted to a level H′, the reference level Gis converted into a level G′, and the level M is set to the level M asit is. As described above, the level conversion based on the tonemapping characteristic TM is performed on the input data from the levelH to the level M, whereby it becomes possible to reduce the imagequality degradation due to the level saturation from the reference levelG to the relative maximum level M.

Operation of the service receiver 200 illustrated in FIG. 25 will bebriefly described. In the reception unit 202, the MP4 distributionstream STM transmitted on the broadcast wave or the network packet fromthe service transmission system 100 is received. The distribution streamSTM is supplied to the container decoder 203.

In the container decoder 203, under the control of the control unit 201,depending on the decoding capability of the receiver 200, the encodedimage data of the required image data is selectively extracted, on thebasis of the “moof” block information and the like, from the MP4distribution stream STM received by the reception unit 202, and suppliedto the video decoder 204.

For example, when the receiver 200 has a decoding capability capable ofprocessing high-frame-rate ultra-high-definition image data, in thecontainer decoder 203, the encoded image data of all the first to fourthimage data are extracted, and supplied to the video decoder 204. Inaddition, for example, when the receiver 200 has a decoding capabilitycapable of processing base-frame-rate ultra-high-definition image data,in the container decoder 203, the encoded image data of the first andthird image data are extracted, and supplied to the video decoder 204.

In addition, for example, when the receiver 200 has a decodingcapability capable of processing high-frame-rate high-definition imagedata, in the container decoder 203, the encoded image data of the firstand second image data are extracted, and supplied to the video decoder204. In addition, for example, when the receiver 200 has a decodingcapability capable of processing base-frame-rate high-definition imagedata, in the container decoder 203, the encoded image data of the firstimage data is extracted, and supplied to the video decoder 204.

In the video decoder 204, decoding processing is applied to the encodedimage data selectively extracted by the container decoder 203, and theHDR transmission video data V1′ is obtained. For example, when thereceiver 200 has a decoding capability capable of processinghigh-frame-rate ultra-high-definition image data, the HDR transmissionvideo data V1′ is image data for display of a high-frame-rateultra-high-definition image. In addition, for example, when the receiver200 has a decoding capability capable of processing base-frame-rateultra-high-definition image data, the HDR transmission video data V1′ isimage data for display of a base-frame-rate ultra-high-definition image.

In addition, for example, when the receiver 200 has a decodingcapability capable of processing high-frame-rate high-definition imagedata, the HDR transmission video data V1′ is image data for display of ahigh-frame-rate high-definition image. In addition, for example, whenthe receiver 200 has a decoding capability capable of processingbase-frame-rate high-definition image data, the HDR transmission videodata V1′ is image data for display of a base-frame-rate high-definitionimage.

In addition, in the video decoder 204, the parameter set and the SEImessage inserted into the encoded image data selectively extracted bythe container decoder 203 are extracted and transmitted to the controlunit 201.

In the control unit 201, on the basis of the conversion characteristicinformation (transferfunction) indicating the photoelectric conversioncharacteristic of the transmission video data V1 inserted into the areaof the VUI of the SPS NAL unit or the electro-optical conversioncharacteristic corresponding to the photoelectric conversioncharacteristic, and the transfer function SEI message (See FIG. 22), theHDR photoelectric conversion characteristic applied to the HDRtransmission video data V1′ is recognized. In addition, in the controlunit 201, on the basis of the dynamic range conversion SEI message (seeFIG. 23), the dynamic range conversion information (conversion table,conversion coefficient) is recognized.

The HDR transmission video data V1′ obtained by the video decoder 204 isconverted from the YCbCr domain to the RGB domain by the YCbCr/RGBconversion unit 205, and then supplied to the HDR electro-opticalconversion unit 206 or the SDR electro-optical conversion unit 207.

In the HDR photoelectric conversion unit 206, the HDR electro-opticalconversion characteristic is applied to the HDR transmission video dataV1′ converted to the RGB domain, and the display video data Vhd fordisplay of the HDR image is obtained. In this case, for the HDRphotoelectric conversion unit 206, under the control of the control unit201, the HDR electro-optical conversion characteristic is set recognizedfrom the VUI or the transfer function SEI message, that is, the HDRelectro-optical conversion characteristic corresponding to the HDRphotoelectric conversion characteristic applied in the transmissionside.

In the SDR electro-optical conversion unit 207, the SDR electro-opticalconversion characteristic is applied to the HDR transmission video dataV1′ converted to the RGB domain, and the display video data Vsd fordisplay of the SDR image is obtained. In this case, when the HDRphotoelectric conversion characteristic applied to the HDR transmissionvideo data V1′ is the characteristic of STD-B67 (HLG), the SDRelectro-optical conversion characteristic is directly applied to the HDRtransmission video data V1′.

In addition, in this case, when the HDR photoelectric conversioncharacteristic applied to the HDR transmission video data V1′ is thecharacteristic of ST2084 (PQ curve), the dynamic range conversion isperformed on the basis of the dynamic range conversion information(conversion table, conversion coefficient) to the HDR transmission videodata V1′, and SDR transmission image data is obtained (see FIG. 26), andthe SDR electro-optical conversion characteristic is applied to the SDRtransmission image data.

As described above, in the transmission/reception system 10 illustratedin FIG. 3, information is inserted into a container (a “moof” block ofan MP4 stream), the information corresponding to information (SPSinformation) that is inserted into each of the predetermined number ofvideo streams and associated with the image data included in the videostreams. Therefore, in the reception side, it becomes easily possible toperform decoding processing by extracting predetermined encoded imagedata from the first to fourth image data included in the predeterminednumber of streams, on the basis of the information, depending ondecoding capability.

In addition, in the transmission/reception system 10 illustrated in FIG.3, the conversion characteristic information indicating the HDRphotoelectric conversion characteristic or the electro-opticalconversion characteristic corresponding to the HDR photoelectricconversion characteristic is inserted into the video stream includingthe encoded image data of the first image data. Therefore, in thereception side, it becomes easily possible to perform appropriateelectro-optical conversion on the basis of the conversion characteristicinformation.

In addition, in the transmission/reception system 10 illustrated in FIG.3, when the high-dynamic-range photoelectric conversion characteristicis the characteristic of the PQ curve, conversion information forconversion of a value of conversion data by the characteristic of the PQcurve to a value of conversion data by the standard-dynamic-rangephotoelectric conversion characteristic is inserted into the videostream including the encoded image data of the first image data.Therefore, when the high-dynamic-range photoelectric conversioncharacteristic is the characteristic of the PQ curve, in a case wherestandard-dynamic-range display is performed, it becomes possible tosatisfactorily obtain the display image data, in the reception side.

2. Modification

Note that, in the above-described embodiment, the description has beenmade assuming a configuration in which, in a case where a base streamand an enhancement stream are transmitted on respective differenttracks, the enhancement stream depends on the extractor. However, thisis merely an example, and in fact it is possible to manage the decodingtiming of the enhancement stream even if there is no extractor.

That is, in the case where the base stream and the enhancement streamare transmitted on the respective different tracks, regarding the trackincluding the enhancement stream, at least the first offset informationof the track is described in a box “baseMediaDecodeTime” in the decodingtime (tfdt) of the track fragment (tfdt) of “moof”, as delay informationin units of 120 Hz, whereby the decoding timing of the enhancementstream is shifted by ( 1/120) seconds with respect to the decodingtiming of the base stream and a similar thing can be achieved.”

In addition, in the above-described embodiment, an example in which thecontainer is of MP4 (ISOBMFF) has been described. However, in thepresent technology, the container is not limited to MP4, and the presenttechnology can be similarly applied even to containers of other formatssuch as MPEG-2 TS and MMT.

In addition, the present technology may also be embodied in theconfigurations described below.

(1) A transmission device including:

an image processing unit that processes high-frame-rateultra-high-definition image data to obtain first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata;

a transmission unit that transmits a container of a predetermined formatincluding a predetermined number of video streams including encodedimage data of the first to fourth image data; and

an information insertion unit that inserts information into thecontainer, the information corresponding to information that is insertedinto each of the predetermined number of video streams and associatedwith image data included in the video streams.

(2) The transmission device according to (1), in which

the container of the predetermined format transmitted by thetransmission unit includes a first video stream including encoded imagedata of the first image data and encoded image data of the second imagedata, and a second video stream including encoded image data of thethird image data and encoded image data of the fourth image data, and

the information insertion unit

inserts the information into the container in a state in which the firstand second video streams are each managed with one track.

(3) The transmission device according to (2), in which

the information insertion unit,

when inserting the information into the container,

performs insertion by grouping information associated with the encodedimage data of the first image data and information associated with theencoded image data of the second image data, for the first video stream,and

performs insertion by grouping information associated with the encodedimage data of the third image data and information associated with theencoded image data of the fourth image data, for the second videostream.

(4) The transmission device according to (2) or (3), in which

a picture of the first image data and a picture of the second image dataare encoded alternately in the first video stream, and

a picture of the third image data and a picture of the fourth image dataare encoded alternately in the second video stream.

(5) The transmission device according to (1), in which

the container of the predetermined format transmitted by thetransmission unit includes a first video stream including encoded imagedata of the first image data and encoded image data of the second imagedata, and a second video stream including encoded image data of thethird image data and encoded image data of the fourth image data, and

the information insertion unit

inserts the information into the container in a state in which the firstand second video streams are each managed with two tracks.

(6) The transmission device according to (5), in which

a picture of the first image data and a picture of the second image dataare encoded alternately in the first video stream, and

a picture of the third image data and a picture of the fourth image dataare encoded alternately in the second video stream.

(7) The transmission device according to (1), in which

the container of the predetermined format transmitted by thetransmission unit includes a first video stream including encoded imagedata of the first image data, a second video stream including encodedimage data of the second image data, a third video stream includingencoded image data of the third image data, and a fourth video streamincluding encoded image data of the fourth image data, and

the information insertion unit

inserts the information in a state in which the first to fourth videostreams are each managed with one track.

(8) The transmission device according to any of (1) to (7), in which

the high-frame-rate ultra-high-definition image data is transmissionimage data having a high-dynamic-range photoelectric conversioncharacteristic given by performing photoelectric conversion by thehigh-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data, and

the information insertion unit

further inserts conversion characteristic information indicating thehigh-dynamic-range photoelectric conversion characteristic or anelectro-optical conversion characteristic corresponding to thehigh-dynamic-range photoelectric conversion characteristic, into a videostream including encoded image data of the first image data.

(9) The transmission device according to (8), in which

the high-dynamic-range photoelectric conversion characteristic is acharacteristic of Hybrid Log-Gamma.

(10) The transmission device according to (8), in which

the high-dynamic-range photoelectric conversion characteristic is acharacteristic of a PQ curve.

(11) The transmission device according to (10), in which

the information insertion unit

further inserts conversion information for conversion of a value ofconversion data by the characteristic of the PQ curve to a value ofconversion data by a standard-dynamic-range photoelectric conversioncharacteristic, into the video stream including the encoded image dataof the first image data.

(12) A transmission method including:

an image processing step of processing high-frame-rateultra-high-definition image data to obtain first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata;

a transmission step, by a transmission unit, of transmitting a containerof a predetermined format including a predetermined number of videostreams including encoded image data of the first to fourth image data;and

an information insertion step of inserting information into thecontainer, the information corresponding to information that is insertedinto each of the predetermined number of video streams and associatedwith image data included in the video streams.

(13) A reception device including

a reception unit that receives a container of a predetermined formatincluding a predetermined number of video streams, in which

the predetermined number of video streams includes first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata that are obtained by processing high-frame-rateultra-high-definition image data,

information is inserted into the container, the informationcorresponding to information that is inserted into each of thepredetermined number of video streams and associated with image dataincluded in the video streams, and

the reception device further includes a processing unit that obtainsimage data by selectively extracting predetermined encoded image datafrom encoded image data of the first to fourth image data and performingdecoding processing, on the basis of the information inserted into thecontainer, depending on decoding capability.

(14) The reception device according to 13, in which

the high-frame-rate ultra-high-definition image data is transmissionimage data having a high-dynamic-range photoelectric conversioncharacteristic given by performing photoelectric conversion by thehigh-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data,

conversion characteristic information indicating the high-dynamic-rangephotoelectric conversion characteristic or an electro-optical conversioncharacteristic corresponding to the high-dynamic-range photoelectricconversion characteristic is inserted into a video stream including theencoded image data of the first image data, and

the processing unit

obtains display image data by performing electro-optical conversion onthe image data obtained by the decoding processing on the basis of theconversion characteristic information.

(15) The reception device according to (13), in which

the high-frame-rate ultra-high-definition image data is transmissionimage data having a high-dynamic-range photoelectric conversioncharacteristic given by performing photoelectric conversion by thehigh-dynamic-range photoelectric conversion characteristic onhigh-dynamic-range image data,

the high-dynamic-range photoelectric conversion characteristic is acharacteristic of a PQ curve,

conversion information for conversion of a value of conversion data bythe characteristic of the PQ curve to a value of conversion data by astandard-dynamic-range photoelectric conversion characteristic isinserted into a video stream including the encoded image data of thefirst image data, and

the processing unit,

when performing standard-dynamic-range display,

obtains standard-dynamic-range transmission image data by performingdynamic range conversion on the image data obtained by the decodingprocessing on the basis of the conversion information, and obtainsdisplay image data by performing electro-optical conversion by astandard-dynamic-range electro-optical conversion characteristic on thestandard-dynamic-range transmission image data.

(16) A reception method including

a reception step, by a reception unit, of receiving a container of apredetermined format including a predetermined number of video streams,in which

the predetermined number of video streams includes first image data foracquisition of a base-frame-rate high-definition image, second imagedata for acquisition of a high-frame-rate high-definition image by beingused with the first image data, third image data for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and fourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata that are obtained by processing high-frame-rateultra-high-definition image data,

information is inserted into the container, the informationcorresponding to information that is inserted into each of thepredetermined number of video streams and associated with image dataincluded in the video streams, and

the reception method further includes a processing step of obtainingimage data by selectively extracting predetermined encoded image datafrom encoded image data of the first to fourth image data and performingdecoding processing, on the basis of the information inserted into thecontainer, depending on decoding capability.

A main feature of the present technology is that, when a containerincluding a predetermined number of video streams related tospatiotemporal scalability is transmitted, information is inserted intothe container (the “moof” block of the MP4 stream), the informationcorresponding to information (SPS information) that is inserted intoeach of the predetermined number of video streams and associated withthe image data included in the video streams, whereby it is facilitatedthat the predetermined encoded image data is extracted from the first tofourth image data included in the predetermined number of streams anddecoding processing is performed, on the basis of the information,depending on the decoding capability, in the reception side (see FIGS.7, 11, and 14).

REFERENCE SIGNS LIST

-   10 Transmission/reception system-   30A, 30B MPEG-DASH based stream distribution system-   31 DASH stream file server-   32 DASH MPD server-   33, 33-1 to 33-N Service receiver-   34 CDN-   35, 35-1 to 35-M Service receiver-   36 Broadcast transmission system-   100 Service transmission system-   101 Control unit-   102 HDR photoelectric conversion unit-   103 RGB/YCbCr conversion unit-   104 Video encoder-   105 Container encoder-   106 Transmission unit-   200, 200A, 200B, 200C, 200D Service receiver-   201 Control unit-   202 Reception unit-   203 Container decoder-   204, 204A, 204B, 204C, 204D Video decoder-   205 YCbCr/RGB conversion unit-   206 HDR electro-optical conversion unit-   207 SDR electro-optical conversion unit

The invention claimed is:
 1. A transmission device, comprising:circuitry configured to process high-frame-rate ultra-high-definitionimage data to obtain first image data for acquisition of abase-frame-rate high-definition image, second image data for acquisitionof a high-frame-rate high-definition image by being used with the firstimage data, third image data for acquisition of a base-frame-rateultra-high-definition image by being used with the first image data, andfourth image data for acquisition of a high-frame-rateultra-high-definition image by being used with the first to third imagedata; transmit a container including (i) a base stream that includesencoded image data of the first image data and encoded image data of thesecond image data, and (ii) an enhancement stream that includes encodedimage data of the third image data and encoded image data of the fourthimage data; and insert, into the container, information in which thebase and enhancement streams are each managed with one track, whereinthe information includes a first representation corresponding to thebase stream and a second representation corresponding to the enhancementstream.
 2. The transmission device according to claim 1, wherein theinformation is a Media Presentation Description (MPD).
 3. Thetransmission device according to claim 1, wherein the circuitry isconfigured to, when inserting the information into the container, insertthe information for the base stream by grouping information associatedwith the encoded image data of the first image data and informationassociated with the encoded image data of the second image data, andinsert the information for the enhancement stream by groupinginformation associated with the encoded image data of the third imagedata and information associated with the encoded image data of thefourth image data.
 4. The transmission device according to claim 1,wherein a picture of the first image data and a picture of the secondimage data are encoded alternately in the base stream, and a picture ofthe third image data and a picture of the fourth image data are encodedalternately in the enhancement stream.
 5. The transmission deviceaccording to claim 1, wherein the high-frame-rate ultra-high-definitionimage data is high-dynamic-range transmission image data obtained byperforming high-dynamic-range photoelectric conversion onhigh-dynamic-range image data, and the circuitry is configured tofurther insert conversion characteristic information indicating acharacteristic of the high-dynamic-range photoelectric conversion or anelectro-optical conversion corresponding to the high-dynamic-rangephotoelectric conversion into the information.
 6. The transmissiondevice according to claim 5, wherein the conversion characteristicinformation indicates a characteristic of Hybrid Log-Gamma.
 7. Thetransmission device according to claim 5, wherein the conversioncharacteristic information indicates a characteristic of a PQ curve. 8.A reception device, comprising: circuitry configured to receive acontainer including (i) a base stream including encoded image data offirst image data and encoded image data of second image data, and (ii)an enhancement stream including encoded image data of third image dataand encoded image data of fourth image data, wherein the first imagedata is for acquisition of a base-frame-rate high-definition image, thesecond image data is for acquisition of a high-frame-ratehigh-definition image by being used with the first image data, the thirdimage data is for acquisition of a base-frame-rate ultra-high-definitionimage by being used with the first image data, and the fourth image datais for acquisition of a high-frame-rate ultra-high-definition image bybeing used with the first to third image data, the container includesinformation in which the base and enhancement streams are each managedwith one track, and the information includes a first representationcorresponding to the base stream and a second representationcorresponding to the enhancement stream; and the circuitry is configuredto obtain image data for display by decoding encoded image data includedin the base and enhancement streams based on the information included inthe container.
 9. The reception device according to claim 8, wherein theinformation is a Media Presentation Description (MPD).
 10. The receptiondevice according to claim 8, wherein the information for the base streamis included in the container by grouping information associated with theencoded image data of the first image data and information associatedwith the encoded image data of the second image data, and theinformation for the enhancement stream is included in the container bygrouping information associated with the encoded image data of the thirdimage data and information associated with the encoded image data of thefourth image data.
 11. The reception device according to claim 8,wherein the information included in the container further includesconversion characteristic information indicating a characteristic of ahigh-dynamic-range photoelectric conversion or an electro-opticalconversion corresponding to the high-dynamic-range photoelectricconversion, and the circuitry is configured to perform electro-opticalconversion on the image data obtained by the decoding processing basedon the conversion characteristic information.
 12. The reception deviceaccording to claim 11, wherein the conversion characteristic informationindicates a characteristic of Hybrid Log-Gamma.
 13. The reception deviceaccording to claim 11, wherein the conversion characteristic informationindicates a characteristic of a PQ curve.
 14. A reception method,comprising receiving, by circuitry, a container including (i) a basestream including encoded image data of first image data and encodedimage data of second image data, and (ii) an enhancement streamincluding encoded image data of third image data and encoded image dataof fourth image data, wherein the first image data is for acquisition ofa base-frame-rate high-definition image, the second image data is foracquisition of a high-frame-rate high-definition image by being usedwith the first image data, the third image data is for acquisition of abase-frame-rate ultra-high-definition image by being used with the firstimage data, and the fourth image data is for acquisition of ahigh-frame-rate ultra-high-definition image by being used with the firstto third image data, the container includes information in which thebase and enhancement streams are each managed with one track, theinformation includes a first representation corresponding to the basestream and a second representation corresponding to the enhancementstream, and the reception method further comprises obtaining, by thecircuitry, image data for display by decoding encoded image dataincluded in the base and enhancement streams based on the informationincluded in the container.
 15. The reception method according to claim14, wherein the information is a Media Presentation Description (MPD).16. The reception method according to claim 14, wherein the informationfor the base stream is included in the container by grouping informationassociated with the encoded image data of the first image data andinformation associated with the encoded image data of the second imagedata, and the information for the enhancement stream is included in thecontainer by grouping information associated with the encoded image dataof the third image data and information associated with the encodedimage data of the fourth image data.
 17. The reception method accordingto claim 14, wherein the information included in the container furtherincludes conversion characteristic information indicating acharacteristic of a high-dynamic-range photoelectric conversion or anelectro-optical conversion corresponding to the high-dynamic-rangephotoelectric conversion, and the reception method further comprisesperforming electro-optical conversion on the image data obtained by thedecoding processing based on the conversion characteristic information.18. The reception method according to claim 17, wherein the conversioncharacteristic information indicates a characteristic of HybridLog-Gamma.
 19. The reception method according to claim 17, wherein theconversion characteristic information indicates a characteristic of a PQcurve.